CN116307654A - Energy hub balance adjustment method based on real-time topology information - Google Patents

Abstract

The invention discloses an energy hub balance adjustment method based on real-time topology information, which relates to the technical field of intelligent energy, a real-time topology information acquisition system is established in an energy hub, the real-time topology information acquisition system comprises a sensor, a controller and a communication module, an energy hub topology map is constructed according to the energy hub topology information acquired by the real-time topology information acquisition system, a balance adjustment strategy of the energy hub is determined according to the energy hub topology map, the balance adjustment strategy comprises regional cooperative adjustment, cross-regional cooperative adjustment and external energy access adjustment, read-write permission of the communication module is acquired, and an administrator and a fault inspector perform corresponding repair measures on energy nodes according to data stored in a data folder in the communication module, so that energy balance of the energy hub is realized.

Description

Energy hub balance adjustment method based on real-time topology information

Technical Field

The invention relates to the technical field of intelligent energy, in particular to an energy hub balance adjustment method based on real-time topology information.

Background

With the continuous change of the energy supply and demand relationship, the balance adjustment problem of the energy hub is more and more serious. The traditional balance adjustment method cannot meet the complex energy supply and demand relation, when partial area energy cannot be kept balanced, a single method for uniformly acquiring energy from an energy supply center is always adopted, the situation that energy is excessive in adjacent areas is not considered, the phenomenon that partial area energy is excessive and partial area energy is insufficient in energy distribution scheduling is caused, in addition, when related equipment at an energy node is in a problem, fault information cannot be acquired in time, and corresponding personnel are arranged to conduct fault elimination, and the problems are all considered.

Disclosure of Invention

In order to solve the above problems, the present invention aims to provide an energy hub balance adjustment method based on real-time topology information.

The aim of the invention can be achieved by the following technical scheme: an energy hub balance adjusting method based on real-time topology information comprises the following steps:

step one: a real-time topology information acquisition system is established in an energy hub, and the real-time topology information acquisition system comprises a sensor, a controller and a communication module;

step two: collecting energy hub topology information according to a real-time topology information collection system, and constructing an energy hub topology graph, wherein the energy hub topology graph comprises energy nodes and energy source pipelines;

step three: the method comprises the steps of preparing a balance adjustment strategy of an energy hub according to an energy hub topological graph, wherein the balance adjustment strategy comprises regional cooperative adjustment, cross-regional cooperative adjustment and external energy access adjustment;

step four: and acquiring the read-write permission of the communication module, and performing corresponding repairing measures on the energy nodes by an administrator and a fault checking personnel according to the data stored in the data folder in the communication module, wherein the repairing measures comprise voltage stabilizing operation and load stabilizing operation.

Further, the functions of the sensor, the controller and the communication module include:

the sensor comprises a pressure sensor, a power sensor and a temperature sensor, wherein the pressure sensor, the power sensor and the temperature sensor are respectively arranged in a first acquisition area, a second acquisition area and a third acquisition area which are divided by an energy hub to acquire pressure data, power data and temperature data;

the controller comprises a storage unit and an adjusting unit, wherein the storage unit stores data, and the adjusting unit is used for adjusting the energy capacity of the energy source node and the opening and closing of the energy source pipeline and the energy source flow rate;

the communication module is provided with a preprocessing unit, and the preprocessing unit processes the energy hub topology information into image data information.

Further, the process of constructing the energy hub topological graph according to the image data information comprises the following steps:

acquiring image data information, wherein the image data information comprises an energy node image set and an energy flow pipeline image set, the energy node image set consists of a plurality of energy nodes, and the energy flow pipeline image set consists of a plurality of energy flow pipelines;

and using one energy node as a hub center node, using other energy nodes as auxiliary connection nodes, using an energy source flow pipeline as a communication line to establish a connection relationship, dynamically changing the number of the auxiliary connection nodes to generate topology points and topology areas, and drawing an energy hub topological graph according to the topology points and the topology areas.

Further, the dynamically changing process includes:

the dynamically changed numerical value is num, num epsilon [3,8], which means that a hub central node is associated with 3 to 8 auxiliary connection nodes, and a regional energy site is formed after the association;

and taking each regional energy station as a topological area, and taking all energy nodes of the topological area as a plurality of topological points, wherein the topological points are provided with an energy storage capacity controller and an energy flow rate controller.

Further, the functions of the energy storage capacity controller and the energy flow rate controller include:

the energy storage capacity controller is provided with different storage capacities, and is used for controlling energy flow rates among topological points, obtaining energy flow time T1, energy flow pipeline length L, cross-sectional area S of the energy flow pipeline, obtaining energy flow time T2, obtaining energy flow rates V according to T1, L, S and T2, V=L×S/(T2-T1) m/S, and setting different standard energy flow rates according to the range of the energy flow pipeline length L.

Further, the process of formulating the balance adjustment strategy according to the energy hub topological graph comprises the following steps:

dividing the whole energy hub into a plurality of adjusting units through the energy hub topological graph, wherein each adjusting unit is used for adjusting regional energy supply;

the regional energy supply adjustment is used for adjusting the inside of a topological region to meet the use requirement of an energy source demander belonging to the topological region, an adjustment unit is provided with an Internet terminal device, and the Internet terminal device is provided with a login unit and an auditing unit;

the energy resource demander acquires an account number and a password through a login unit and an auditing unit according to the identity information, and is connected to the Internet terminal equipment to upload an energy resource demand form;

the internet terminal equipment acquires an energy demand form and combines an energy hub topological graph to formulate a corresponding balance adjustment strategy.

Further, the balance adjustment strategy and the corresponding content thereof comprise:

the energy demand form comprises energy demand, different balance adjustment strategies are given to the adjustment units according to the energy demand and the total energy capacity, and the total energy capacity is obtained by accumulating storage capacities corresponding to topological nodes included in the topological area;

if the balance adjustment strategy is the collaborative adjustment of the same area, the storage capacity of all the topology nodes is adjusted in the same topology area, so that the storage capacity of each topology node is more than or equal to the set primary storage capacity;

if the balance adjustment strategy is cross-region cooperative adjustment, acquiring the total energy capacity of other topological areas, and when the storage capacity of all topological nodes in other topological areas is larger than or equal to the primary storage capacity, increasing the storage capacity of all topological nodes in the current topological area to the primary storage capacity or more;

if the balance adjustment strategy is cross-region cooperative adjustment, an administrator schedules an energy scheduling vehicle to perform energy supply of a topology region, and the storage capacity of all current topology nodes after the energy supply is larger than or equal to the primary storage capacity.

Further, the process of repairing the energy node includes:

the method comprises the steps of obtaining read-write permission of a communication module, obtaining a data folder, uploading the data folder into a data analysis unit arranged in a real-time topology information acquisition system, analyzing the data in real time by the data analysis unit to obtain a load state, a power state and a voltage and current state associated with each energy node, and performing voltage stabilizing operation and repairing measures of the voltage stabilizing operation.

Compared with the prior art, the invention has the beneficial effects that: the energy nodes can be monitored in real time through the real-time topology information acquisition system, the energy supply and demand relation change is responded quickly according to a topology diagram and a balance adjustment strategy, energy flow pipelines are arranged between the energy nodes, corresponding standard energy flow rates are arranged according to the lengths of the energy flow pipelines, so that the energy flow rates can be stabilized within an average numerical range, an auditing unit is arranged to prevent non-energy demander from acquiring energy related data information and causing data leakage, and each energy node can keep balanced operation on the premise that the lowest energy balance maintains storage capacity by different balance adjustment strategies; and acquiring related data in the data folder, analyzing the related data in real time through a data analysis unit, and carrying out corresponding repairing measures so as to timely eliminate potential safety hazards of energy nodes.

Drawings

FIG. 1 is a flow chart of the present invention.

Detailed Description

As shown in fig. 1, the energy hub balance adjustment method based on real-time topology information includes the following steps:

step one: a real-time topology information acquisition system is established in an energy hub, and the real-time topology information acquisition system comprises a sensor, a controller and a communication module;

step two: collecting energy hub topology information according to a real-time topology information collection system, and constructing an energy hub topology graph, wherein the energy hub topology graph comprises energy nodes and energy source pipelines;

step three: the method comprises the steps of preparing a balance adjustment strategy of an energy hub according to an energy hub topological graph, wherein the balance adjustment strategy comprises regional cooperative adjustment, cross-regional cooperative adjustment and external energy access adjustment;

step four: and acquiring the read-write permission of the communication module, and performing corresponding repairing measures on the energy nodes by an administrator and a fault checking personnel according to the data stored in the data folder in the communication module, wherein the repairing measures comprise voltage stabilizing operation and load stabilizing operation.

Constructing a real-time topology information acquisition system, wherein the real-time topology information acquisition system is arranged in the energy hub and used for acquiring the topology information of the energy hub, and the real-time topology information acquisition system consists of a sensor, a controller and a communication module;

the sensor comprises a pressure sensor, a power sensor and a temperature sensor, wherein the pressure sensor is arranged in a first acquisition area of the energy hub, the temperature sensor is arranged in a second acquisition area of the energy hub, and the power sensor is arranged in a third acquisition area of the energy hub;

respectively acquiring pressure data, electric power data and temperature data through a pressure sensor, an electric power sensor and a temperature sensor; the pressure data, the power data and the temperature data are provided with a filtering threshold value and a packaging threshold value;

when the value of each item of data acquired by the sensor reaches a filtering threshold value, comparing the pressure data, the electric power data and the temperature data with a preset numerical range of the filtering threshold value, and filtering each item of data which is not in the numerical range of the filtering threshold value to generate filtering data;

after the generated filtering data reach the set encapsulation threshold range, encapsulating the filtering data into a data folder, and uploading the data folder to a communication module in a mode of establishing an encryption channel;

the controller comprises a storage unit and an adjusting unit, wherein the storage unit stores the filtered data, and the filtered data is received by the storage unit for storage when the filtered data does not reach the packaging threshold value;

the adjusting unit is used for adjusting the energy capacity of the energy source node in the energy source junction and adjusting the opening and closing of the energy source flow pipeline and the energy source flow rate;

the sensor data and the data represented by the energy nodes are collectively called energy hub topology information, the energy hub topology information is uploaded into a communication module, a preprocessing unit is arranged at the communication module, and the preprocessing unit processes the energy hub topology information into image data information;

acquiring image data information represented by energy hub topology information, and constructing an energy hub topology map according to the image data information, wherein the image data information comprises an energy node image set and an energy source pipeline image set;

the energy node image set consists of a plurality of energy nodes, and the energy flow pipeline image set consists of a plurality of energy flow pipelines;

numbering the energy nodes and the energy flow pipelines respectively, and obtaining the number n of all the energy nodes and the number m of the energy flow pipelines, wherein i and j are recorded, i=1, 2,3, … …, n and n are natural numbers, j=1, 2,3, … …, m and m are natural numbers; taking one energy node as a hub center node, other nodes as auxiliary connection nodes, and energy source pipelines as communication lines, wherein the hub center node establishes a connection relationship with the auxiliary connection nodes through the communication lines to dynamically change the number of the auxiliary connection nodes;

dynamically changing numerical values are recorded as num, num is an integer, num epsilon [3,8], namely, a hub central node is associated with 3 to 8 auxiliary connection nodes, after the association, an area energy station is formed, the area energy station is recorded as omega, the area energy station has a corresponding station set, the area energy station and the station set have the following relation, omega= { i, R }, R= { num, j }, wherein i is the number of the hub central node, j is the number of the auxiliary connection nodes, and the set R is a set formed by a communication line connected with the hub central node and the auxiliary connection nodes;

taking each regional energy station as a topological area, taking all energy nodes of the topological area as a plurality of topological points, and setting an energy storage capacity controller and an energy flow rate controller by the topological points;

the energy storage capacity controller is provided with different storage capacities, wherein the storage capacities comprise a primary storage capacity, a secondary storage capacity and a tertiary storage capacity, and the size relation of the storage capacities is as follows: primary storage capacity < secondary storage capacity < tertiary storage capacity;

the energy flow rate controller is used for controlling energy flow rates of energy flowing in the energy flow pipeline between topological points, taking two topological points as an example, respectively marking as a topological point A and a topological point B, and enabling the flowing direction of the energy flow to be forward from the topological point A to the topological point B, and conversely, to be reverse;

when energy begins to flow out of the topological point A, acquiring a starting time which is marked as T1, acquiring the length of an energy source pipeline between the topological point A and the topological point B, marking as L, acquiring the cross-sectional area of a branch line of the energy source pipeline, marking as S, and acquiring the time of the energy source flowing into the topological point B, marking as T2;

obtaining energy flow rates according to T1, L, S and T2, which are denoted as V, and V=L×S/(T2-T1) m/S, setting different standard energy flow rates according to the range of the energy flow pipeline length L between topological points, which are denoted as V _L The correspondence is as follows:

when L epsilon [0, 30]V at the time of _L Setting the width to be 20-30 m 2 m/s;

when L epsilon (30, 75)]V at the time of _L Setting the width at 35-45 m/s;

when L epsilon (75,100)]V at the time of _L Is arranged as55～80m³/s；

Summarizing all topological areas, topological points and storage capacity and energy flow rate associated with an energy storage capacity controller and an energy flow rate controller which are arranged at the topological points, and generating an energy hub topological diagram;

it should be noted that, through setting the filtering threshold, the values which do not accord with the specified range are filtered in advance, so that the data volume to be processed is reduced, the number of regional energy stations formed by a plurality of energy nodes is dynamically changed, so that the energy hub is constructed to be more highly coupled, different standard energy flow rates are set according to the lengths of the energy flow pipelines, and the flow rate of the energy can be kept stable within an average value range even if the lengths of the pipelines are inconsistent.

Acquiring an energy hub topological graph, and preparing a corresponding balance adjustment strategy according to the energy hub topological graph;

specifically, the process of formulating the balance adjustment strategy according to the energy hub topological graph comprises the following steps:

dividing the whole energy hub into a plurality of adjusting units through the energy hub topological graph, wherein the adjusting units are in one-to-one correspondence with topological areas of the energy hub topological graph, and each adjusting unit is used for carrying out regional energy supply adjustment;

the regional energy supply adjustment is to adjust the energy in one region to meet the use requirement of the energy demander belonging to the region, wherein the energy demander comprises enterprise users and private users;

each adjusting unit is provided with an internet terminal device, and the internet terminal device is provided with a login unit and an auditing unit;

the energy resource demander registers an account through identity information, the identity information of an enterprise user comprises an enterprise contact phone, an enterprise address and an enterprise business license serial code, the identity information of a private user comprises a mobile phone number, an identity card number and a home address, the identity information is input into an auditing unit, an administrator of the auditing unit audits the identity information, the account and a password are issued after the auditing is successful, the issued account and password are stored in a cloud server synchronously, the password is an initial password, and the initial password is allowed to be changed;

after the enterprise user and the private user acquire the account number and the password, the login unit performs login operation, the acquired account number and password are compared with the account number and password stored in the cloud server, and the right for connecting the internet terminal equipment is acquired after the comparison is successful;

after logging in the Internet terminal equipment, the energy resource demander uploads the energy resource demand form into the Internet terminal equipment, and the Internet terminal equipment acquires the energy resource demand form and combines with the energy resource hub topological graph to formulate a corresponding balance adjustment strategy;

the content recorded in the energy demand form comprises energy demand, energy demand time and energy demand priority, and the balance adjustment strategy comprises regional cooperative adjustment, cross-regional cooperative adjustment and external energy access adjustment;

according to the content recorded in the energy demand form and the energy total capacity of the topological area, different balance adjustment strategies are given to adjustment units corresponding to different topological areas in the energy hub topological graph, the energy total capacity is obtained by storage capacities corresponding to topological nodes included in the topological area, the storage capacities recorded by the storage capacity controllers of a plurality of topological nodes are obtained, and the energy total capacity of the topological area is obtained in an accumulated mode;

the total energy capacity of the topological area is recorded as C, the corresponding energy demand is recorded as C', the primary storage capacity of the topological node is recorded as C1, the secondary storage capacity is recorded as C2, and the tertiary storage capacity is recorded as C3;

if C is more than or equal to C', obtaining the number of topological nodes in the topological area, marking as N, obtaining the average energy capacity of a single topological node, marking as C _{Average of} ，C _{Average of} ＝C/N；

If C _{Average of} And (3) carrying out regional collaborative adjustment, wherein the content of the regional collaborative adjustment is as follows: in the same topological area, the storage capacity of all topological nodes is regulated to ensure that the storage capacity of each topological node reaches c1 and above;

if C _{Average of} < c1, then a trans-regional co-modulation is performed, whichThe content is as follows: establishing connection of other topological areas adjacent to the topological area, obtaining the total energy capacity of the other topological areas, and on the premise that the storage capacity of all topological nodes of the other topological areas is larger than or equal to c1, increasing the storage capacity of all topological nodes of the current topological area to c1 or above;

if the storage capacity of each topological node in the other topological areas is not kept to be more than or equal to c1 after the inter-area cooperative adjustment of the other topological areas adjacent to the current topological area, performing external energy access adjustment;

the external energy access adjustment is carried out under the condition that C is less than C', an administrator schedules an energy scheduling vehicle, the energy scheduling vehicle supplements energy of a topological area according to energy demand priority and energy demand time in an energy demand form, and the storage capacity of each topological node after energy supplement is more than or equal to C1;

the method is characterized in that identity information is input by an energy source demander, an account number and a password are issued after the verification is successful, the situation that a non-energy source demander logs in an internet terminal device to cause data leakage is prevented, different balance adjustment strategies are formulated according to an energy hub topological graph, the same-area cooperative adjustment is firstly carried out to ensure that all energy nodes in one topological area can reach the minimum energy balance maintenance storage capacity, when the area cooperative adjustment cannot ensure that each energy node can reach the minimum energy balance maintenance storage capacity, the energy source of other topological areas is accessed by using cross-area cooperative adjustment, so that all energy nodes in the current topological area and adjacent topological areas can reach the minimum energy balance maintenance storage capacity, and when the cross-area cooperative adjustment cannot solve the energy balance requirement, the minimum energy balance maintenance storage capacity is the primary storage capacity by adopting external energy source access adjustment.

Acquiring the read-write permission of the communication module, acquiring a data folder in the communication module after the read permission in the read-write permission is acquired, and acquiring pressure data, electric power data and temperature data acquired by a corresponding sensor in the data folder;

the pressure data, the power data and the temperature data are uploaded into a data analysis unit arranged in the real-time topology information acquisition system in real time, and the data analysis unit analyzes the data in real time to obtain a load state, a power state and a voltage and current state associated with each energy node;

the load states of the energy nodes comprise overload states, proper load states and low load states, wherein the overload states and the low load states are abnormal load states, the energy node fault I is correspondingly generated, and the energy node normally operates in the proper load state;

the power states of the energy nodes comprise a high-voltage power state, a stable-voltage power state and a low-voltage power state, wherein the high-voltage power state and the low-voltage power state are abnormal power states, and the energy nodes correspondingly generate a second energy node fault, and in the state of the stable-voltage power, the power of the energy nodes is normal;

the energy source flow rate controller is set to be open authority in the normal voltage and current state of the energy source node, and when the energy source node is in the abnormal voltage and current state, the energy source flow rate controller is set to be control authority, the control authority is connected to an administrator, and the administrator obtains the control authority to control the energy source flow rate controller;

generating a fault report by converging the first energy node fault and the second energy node fault, and uploading the fault report to a fault inspector, wherein the fault inspector is provided with an overhaul instrument which is provided with a voltage stabilizing operation function and a load stabilizing operation function;

the fault troubleshooting personnel respectively repairs and removes the fault of the first energy node fault and the second energy node fault in the fault report through the load stabilizing operation function and the voltage stabilizing operation function, traverses all the energy nodes, and preliminarily locates the abnormal energy nodes;

carrying out load stabilizing operation on the abnormal energy nodes, wherein the load stabilizing operation is to increase the load of the energy nodes, and the value of the increased load is displayed on a display screen of an overhaul instrument in real time until the energy load reaches the load value range corresponding to the proper load;

when the pressurization operation is carried out, the power is displayed in real time through a display screen on the overhaul instrument, and when the power of the energy node reaches a power value corresponding to the stabilized power, the power increase is stopped;

the load state, the power state and the voltage and current state associated with each energy node are obtained after the real-time analysis of the pressure data, the power data and the temperature data in the data folder by the data analysis unit, and corresponding repair measures are carried out, so that potential safety hazards of the energy nodes are eliminated in time.

The above embodiments are only for illustrating the technical method of the present invention and not for limiting the same, and it should be understood by those skilled in the art that the technical method of the present invention may be modified or substituted without departing from the spirit and scope of the technical method of the present invention.

Claims (8)

1. The energy hub balance adjustment method based on the real-time topology information is characterized by comprising the following steps of:

step one: a real-time topology information acquisition system is established in an energy hub, and the real-time topology information acquisition system comprises a sensor, a controller and a communication module;

step two: collecting energy hub topology information according to a real-time topology information collection system, and constructing an energy hub topology graph, wherein the energy hub topology graph comprises energy nodes and energy source pipelines;

step three: the method comprises the steps of preparing a balance adjustment strategy of an energy hub according to an energy hub topological graph, wherein the balance adjustment strategy comprises regional cooperative adjustment, cross-regional cooperative adjustment and external energy access adjustment;

step four: and acquiring the read-write permission of the communication module, and performing corresponding repairing measures on the energy nodes by an administrator and a fault checking personnel according to the data stored in the data folder in the communication module, wherein the repairing measures comprise voltage stabilizing operation and load stabilizing operation.

2. The method for adjusting energy hub balance based on real-time topology information according to claim 1, wherein the functions of the sensor, the controller and the communication module include:

the sensor comprises a pressure sensor, a power sensor and a temperature sensor, wherein the pressure sensor, the power sensor and the temperature sensor are respectively arranged in a first acquisition area, a second acquisition area and a third acquisition area which are divided by an energy hub to acquire pressure data, power data and temperature data;

the controller comprises a storage unit and an adjusting unit, wherein the storage unit stores data, and the adjusting unit is used for adjusting the energy capacity of the energy source node and the opening and closing of the energy source pipeline and the energy source flow rate;

the communication module is provided with a preprocessing unit, and the preprocessing unit processes the energy hub topology information into image data information.

3. The method for adjusting energy hub balance based on real-time topology information according to claim 2, wherein the process of constructing an energy hub topology map based on the image data information comprises:

acquiring image data information, wherein the image data information comprises an energy node image set and an energy flow pipeline image set, the energy node image set consists of a plurality of energy nodes, and the energy flow pipeline image set consists of a plurality of energy flow pipelines;

and using one energy node as a hub center node, using other energy nodes as auxiliary connection nodes, using an energy source flow pipeline as a communication line to establish a connection relationship, dynamically changing the number of the auxiliary connection nodes to generate topology points and topology areas, and drawing an energy hub topological graph according to the topology points and the topology areas.

4. The method for adjusting energy hub balance based on real-time topology information according to claim 3, wherein the dynamically changing process comprises:

the dynamically changed numerical value is num, num epsilon [3,8], which means that a hub central node is associated with 3 to 8 auxiliary connection nodes, after the association, regional energy stations are formed, each regional energy station is used as a topological area, all energy nodes of the topological area are used as a plurality of topological points, and an energy storage capacity controller and an energy flow rate controller are arranged on the topological points.

5. The method for adjusting balance of an energy hub based on real-time topology information of claim 4, wherein the functions of said energy storage capacity controller and energy flow rate controller comprise:

the energy storage capacity controller is provided with different storage capacities, and is used for controlling energy flow rates among topological points, obtaining energy flow time T1, energy flow pipeline length L, cross-sectional area S of the energy flow pipeline, obtaining energy flow time T2, obtaining energy flow rates V according to T1, L, S and T2, V=L×S/(T2-T1) m/S, and setting different standard energy flow rates according to the range of the energy flow pipeline length L.

6. The method for adjusting balance of an energy hub based on real-time topology information according to claim 5, wherein the process of formulating a balance adjustment strategy according to the energy hub topology map comprises:

dividing the whole energy hub into a plurality of adjusting units through the energy hub topological graph, wherein each adjusting unit is used for adjusting regional energy supply;

the regional energy supply regulation is used for regulating the use requirement of an energy source demand person belonging to a topological region so as to meet the use requirement of the energy source demand person belonging to the topological region, the regulation unit is provided with an Internet terminal device, the Internet terminal device is provided with a login unit and an auditing unit, the energy source demand person obtains an account number and a password according to identity information through the login unit and the auditing unit and is connected to the Internet terminal device to upload an energy source demand form, and the Internet terminal device obtains the energy source demand form and combines an energy source hub topological diagram to formulate a corresponding balance regulation strategy.

7. The method for adjusting balance of an energy hub based on real-time topology information according to claim 6, wherein the balance adjustment strategy and the corresponding content thereof comprise:

the energy demand form comprises energy demand, different balance adjustment strategies are given to the adjustment units according to the energy demand and the total energy capacity, and the total energy capacity is obtained by accumulating storage capacities corresponding to topological nodes included in the topological area;

if the balance adjustment strategy is the same-area cooperative adjustment, the storage capacity of all the topology nodes is adjusted in the same topology area, so that the storage capacity of each topology node is larger than or equal to the set primary storage capacity, if the balance adjustment strategy is the cross-area cooperative adjustment, the total energy capacity of other topology areas is obtained, when the storage capacity of all the topology nodes in the other topology areas is larger than or equal to the primary storage capacity, the storage capacity of all the topology nodes in the current topology area is increased to be larger than or equal to the primary storage capacity, if the balance adjustment strategy is the cross-area cooperative adjustment, an administrator schedules an energy scheduling vehicle to perform energy supply of the topology area, and the storage capacity of all the current topology nodes after the energy supply is larger than or equal to the primary storage capacity.

8. The method for adjusting energy hub balance based on real-time topology information according to claim 7, wherein the step of repairing the energy node comprises:

the method comprises the steps of obtaining read-write permission of a communication module, obtaining a data folder, uploading the data folder into a data analysis unit arranged in a real-time topology information acquisition system, analyzing the data in real time by the data analysis unit to obtain a load state, a power state and a voltage and current state associated with each energy node, and performing voltage stabilizing operation and repairing measures of the voltage stabilizing operation.

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