CN116151594A - Low-carbon scheduling method for comprehensive energy system with electric heat cooperation - Google Patents

Abstract

The invention provides a low-carbon scheduling method of an electric-thermal cooperative comprehensive energy system, which aims at the scene of an electric, gas, thermal and other dimensional multi-energy complementary comprehensive energy system, and utilizes a convolutional neural network deep learning algorithm to construct a power grid low-carbon scheduling model by analyzing the optimal scheduling method of various capacity and energy utilization equipment. The method comprises the steps of taking target cooperative equipment with multi-energy conversion as fusion corresponding equipment and target cooperative equipment without multi-energy conversion as fixed corresponding equipment, taking an energy sequence table matched with each fusion corresponding equipment and fixed corresponding equipment as energy input data, inputting the obtained energy input data into a power grid low-carbon scheduling model based on a convolution neural algorithm, obtaining a low-carbon scheduling strategy corresponding to a target area after data processing, obtaining an optimal utilization mode and a control strategy of each energy in a day through carbon capture by combining historical data, and constructing a cooperative operation strategy of comprehensive energy system in dimensions of electricity, gas, heat and the like, so that the carbon emission value in the target area is lower.

Description

Low-carbon dispatching method for integrated energy system based on electrical and thermal coordination

technical field

The invention relates to data processing technology, in particular to a low-carbon scheduling method for an integrated energy system with electrical and thermal coordination.

Background technique

The integrated energy system refers to the use of advanced physical information technology and innovative management models in a certain area to integrate various energy sources such as coal, oil, natural gas, electric energy, and thermal energy in a certain area, and to achieve coordinated planning among various heterogeneous energy subsystems. Optimize operation, collaborative management, interactive response and mutual assistance. While meeting the diversified energy demand within the system, it is necessary to effectively improve energy utilization efficiency and promote a new integrated energy system for sustainable energy development.

In the current integrated energy system control process, due to the diversity of equipment in the system, it is difficult to optimize the control of the system from a global perspective and achieve lower data requirements in carbon emissions. Therefore, how to build a coordinated operation strategy of electricity, gas, and heat in an integrated energy system to make the carbon emissions in the target area lower has become an urgent problem to be solved.

Contents of the invention

The embodiment of the present invention provides a low-carbon scheduling method for an integrated energy system in which electricity and heat are coordinated, and constructs a coordinated operation strategy of electricity, gas, and heat in an integrated energy system, so that the carbon emission value in the target area is low.

The first aspect of the embodiments of the present invention provides a low-carbon scheduling method for an integrated energy system with electrical and thermal coordination, including:

Based on the equipment energy supply structure diagram, the electrical and thermal energy supply equipment in the target area is obtained as the equipment to be screened, and the equipment to be screened is screened according to different dimensions according to the equipment screening specifications to obtain multiple target collaborative equipment;

Obtain the electrical and thermal data in the target area, and filter the electrical and thermal data according to different dimensions according to the data screening specifications to obtain multiple energy sequence lists;

Determine the target cooperative equipment with multi-energy conversion as the fusion corresponding equipment, and the target cooperative equipment without multi-energy conversion as the fixed corresponding equipment, and determine the energy sequence list corresponding to each fusion corresponding equipment and fixed corresponding equipment as energy input data;

Construct the corresponding low-carbon dispatching model, input energy input data into the low-carbon dispatching model for data processing, and obtain the corresponding low-carbon dispatching strategy for the target area;

Obtain the corresponding energy demand information in the target area in real time, and generate control strategies for fusion corresponding equipment and fixed corresponding equipment according to energy demand information and low-carbon dispatching strategies.

Optionally, in a possible implementation of the first aspect, the electric and thermal energy supply equipment in the target area is obtained as the equipment to be screened based on the equipment energy supply structure diagram, and the target collaborative equipment is selected according to different dimensions according to the equipment screening specifications. Perform screening to obtain multiple target collaborative devices, including:

Determine the electrical and thermal energy supply equipment as the equipment to be screened in the equipment energy supply structure diagram, and obtain the input equipment and output equipment corresponding to the equipment to be screened;

If the input device is a single fixed device, then obtain the connection relationship of all output devices according to the device energy supply structure diagram, if it is judged that all the output devices obtained are only connected to the device to be screened, then the Input device and output device culling;

Count all un-rejected devices to be screened as energy-supply coordination devices, count all output devices connected to energy-supply coordination devices as energy-use coordination devices, and obtain target coordination devices according to the energy-supply coordination devices and energy-use coordination devices.

Optionally, in a possible implementation of the first aspect, the acquisition of electrical and thermal data in the target area is performed according to data screening specifications to filter the electrical and thermal data according to different dimensions to obtain multiple energy sequence tables, including:

Obtaining the electrical thermal data corresponding to all the equipment in the preset time period by taking the equipment in the target area as a unit, and the electrical thermal data includes electrical thermal information corresponding to multiple sub-time periods;

According to the electrical thermal information corresponding to multiple sub-time periods, the electrical thermal information corresponding to the average period is obtained, and the energy sequence table is generated according to the electrical thermal information corresponding to the average period, and the electrical thermal information corresponding to all sub-time periods is eliminated.

Optionally, in a possible implementation manner of the first aspect, the determination of the target cooperative device with multi-energy conversion as the fusion corresponding device and the target cooperative device without multi-energy conversion as the fixed corresponding device is determined to be related to each Energy input data is generated by fusing corresponding equipment and energy sequence tables corresponding to fixed corresponding equipment, including:

Determine the energy supply coordination equipment with multi-energy conversion as the first energy supply equipment, and determine the energy supply coordination equipment without multi-energy conversion as the second energy supply equipment;

Determine the energy-using coordinated equipment with multi-energy conversion as the first energy-using equipment, and determine the energy-using coordinated equipment without multi-energy conversion as the second energy-using equipment;

The fusion corresponding equipment includes the first energy supply equipment or the first energy consuming equipment, the fixed corresponding equipment includes the second energy supply equipment or the second energy consuming equipment, and it is determined that the first energy supply equipment, the second energy supply equipment, the second energy supply equipment The energy sequence tables corresponding to the first energy-consuming equipment and the second energy-consuming equipment generate energy input data.

Optionally, in a possible implementation of the first aspect, the construction of a corresponding low-carbon dispatch model, input energy input data into the low-carbon dispatch model for data processing, and obtain the low-carbon dispatch strategy corresponding to the target area ,include:

Construct a corresponding low-carbon scheduling model, and the low-carbon scheduling model determines the first energy supply equipment or the second energy supply equipment connected to the second energy-consuming equipment based on the equipment energy supply structure diagram;

Adding a first scheduling tag to the determined first energy supply device or second energy supply device, the first scheduling tag has the identity information of the second energy consuming device and the energy sequence list corresponding to the second energy consuming device;

The low-carbon scheduling model determines the first energy supply equipment and/or the second energy supply equipment connected to the first energy-consuming equipment based on the equipment energy supply structure diagram;

If the sum of the first energy supply device and/or the second energy supply device is 2, then compare the first energy supply device with the second energy supply device, and determine that for the first energy supply device in different sub-time periods Equipment with low carbon emissions is used as the third energy supply equipment;

The low-carbon scheduling model generates second scheduling labels of different sub-time periods and adds them to the corresponding third energy supply equipment. The second scheduling label has the identity information of the first energy-consuming equipment, the electrical thermal information.

Optionally, in a possible implementation manner of the first aspect, it also includes:

If the sum of the first energy supply equipment or the second energy supply equipment is greater than 2, then all the first energy supply equipment and the second energy supply equipment are compared, and it is determined that for the first energy supply equipment in different sub-time periods carbon emissions;

The low-carbon scheduling model generates the first scheduling label group corresponding to the first energy supply equipment or the second energy supply equipment, and according to the carbon emissions corresponding to the first energy supply equipment or the second energy supply equipment The second scheduling tags are sorted, and the corresponding second scheduling tags are respectively added to the corresponding first energy supply device or the second energy supply device.

Optionally, in a possible implementation of the first aspect, the construction of a corresponding low-carbon dispatch model, input energy input data into the low-carbon dispatch model for data processing, and obtain the low-carbon dispatch strategy corresponding to the target area ,include:

The low-carbon scheduling model determines multiple input devices connected to the first energy supply device based on the device energy supply structure diagram;

Calculate the carbon emissions of multiple input devices corresponding to the first energy supply device in the working state of the corresponding sub-time period, and add the third scheduling label to the input devices corresponding to the input devices with less carbon emissions;

If the number of input devices is greater than 2, then generate the second scheduling tag group corresponding to the multiple input devices, sort the third scheduling tags of the second scheduling tag group according to the carbon emissions corresponding to each input device, and sort the corresponding Add corresponding third scheduling tags to the input devices respectively, and each third scheduling tag has corresponding sequence information;

The low-carbon scheduling model generates corresponding low-carbon scheduling strategies according to all the first scheduling labels, the second scheduling labels and the third scheduling labels.

Optionally, in a possible implementation of the first aspect, the real-time acquisition of corresponding energy demand information in the target area, and generation of control for fusion corresponding equipment and fixed corresponding equipment according to energy demand information and low-carbon scheduling strategies strategies, including:

Obtain the preset working time of all the first energy-consuming equipment and the second energy-consuming equipment in the target area, and determine the first energy-consuming equipment that will work near the current moment in the preset working time of all the first energy-consuming equipment and the second energy-consuming equipment Three energy-using equipment and fourth energy-using equipment;

Determining the first energy supply device and/or the second energy supply device corresponding to the third energy use device and the fourth energy use device, according to the first scheduling label configured by the first energy supply device and/or the second energy supply device , the second scheduling label determines the target energy supply equipment that supplies energy to the third energy consumption equipment and the fourth energy consumption equipment;

The target input device corresponding to the target energy supply device is determined according to the third scheduling tag configured on the input device.

Optionally, in a possible implementation manner of the first aspect, the determination of the third energy-using The target energy supply equipment supplied by the equipment and the fourth energy-consuming equipment, including:

Determining the load information of the third energy-using equipment and the fourth energy-consuming equipment corresponding to the first energy supplying equipment and/or the second energy supplying equipment, if the first energy supplying equipment and/or the second energy supplying equipment meet the load information, based on the priority order of the first scheduling label and the second scheduling label, the first energy supply device and/or the second energy supply device are controlled, and the third energy consumption device and the fourth energy consumption equipment are supplied with energy;

If the first energy supply equipment and/or the second energy supply equipment do not meet the load information, the third energy supply equipment is transferred from the current first energy supply equipment or the second energy supply equipment to other first energy supply equipment equipment or a second energy supply device;

Determine the target energy supply equipment that supplies energy to the third energy consumption equipment and the fourth energy consumption equipment.

Optionally, in a possible implementation manner of the first aspect, the determining the target input device corresponding to the target energy supply device according to the third scheduling tag configured on the input device includes:

Identify all input devices connected to the target energy supply device;

If the number of input devices is 1, take one corresponding input device as the target input device;

If the number of input devices is greater than 1, then determine the corresponding input device as the target input device according to the order of the second scheduling tag in the second scheduling tag group;

If the load information of the target input device does not meet the requirements, the first energy supply device of the target input device that does not meet the requirements is connected to other connected input devices;

The input device that supplies power to the first power supply device and the second power supply device is determined as the target input device.

The second aspect of the embodiments of the present invention provides a low-carbon dispatching system for an integrated energy system with electrical and thermal coordination, including:

The screening module is used to obtain the electrical and thermal energy supply equipment in the target area as the equipment to be screened based on the equipment energy supply structure diagram, and screen the equipment to be screened according to the equipment screening specifications in different dimensions to obtain multiple target collaborative equipment;

The sequence table module is used to obtain the electrical thermal data in the target area, and filter the electrical thermal data according to different dimensions according to the data screening specifications to obtain multiple energy sequence tables;

The classification module is used to determine the target cooperative equipment with multi-energy conversion as the fusion corresponding equipment, and the target cooperative equipment without multi-energy conversion as the fixed corresponding equipment, and determine the energy sequence list corresponding to each fusion corresponding equipment and fixed corresponding equipment as energy input data;

The strategy module is used to construct the corresponding low-carbon dispatching model, input energy input data into the low-carbon dispatching model for data processing, and obtain the corresponding low-carbon dispatching strategy for the target area;

The scheduling module is used to obtain the corresponding energy demand information in the target area in real time, and generate a control strategy for the fusion corresponding equipment and the fixed corresponding equipment according to the energy demand information and the low-carbon scheduling strategy.

Beneficial effects: 1. This scheme will sort out and classify the electrical and thermal energy supply equipment in the target area in combination with the equipment energy supply structure diagram, and then combine the electrical and thermal data to obtain the corresponding energy sequence table, and set up a low-carbon dispatching model, which will The energy input data is input into the low-carbon dispatching model for data processing to obtain the low-carbon dispatching strategy corresponding to the target area. At the same time, when performing control, it will combine the energy demand information to generate a control strategy for the fusion corresponding equipment and fixed corresponding equipment. Through the above method, this scheme can build a coordinated operation strategy of electricity, gas and heat in the comprehensive energy system, so that the carbon emission value in the target area is low.

2. This solution will combine the type of input device to screen the device to be screened in a corresponding way. When the input device is a single fixed device, it will judge and screen based on the connection relationship of the output device, so as to obtain the target collaborative device. In the process of obtaining the low-carbon dispatch strategy, this scheme will add the first dispatch label to the determined first energy supply equipment or the second energy supply equipment, and add the second dispatch label to the third energy supply equipment, and input the equipment Add the third scheduling label to the input device corresponding to the small carbon emission, and combine the first scheduling label, the second scheduling label and the third scheduling label to perform comprehensive scheduling, so that the carbon emission value in the target area is relatively low.

3. When this plan uses the low-carbon dispatching strategy for scheduling, it will first obtain the preset working hours of all the first energy-consuming equipment and the second energy-consuming equipment in the target area, and then It is determined that the current time is close to the energy-consuming equipment, so as to determine the third energy-consuming equipment and the fourth energy-consuming equipment that need to work, and then combine the configured first scheduling label and second scheduling label to determine the third energy-using equipment and the fourth energy-using equipment. The target energy supply device that the energy supply equipment supplies. In addition, this scheme also considers the load information of the third energy-consuming equipment and the fourth energy-consuming equipment, and transfers the equipment when the load is overloaded, and obtains the third energy-consuming equipment and the fourth energy-consuming equipment that meet the scheduling requirements as the target Energy supply equipment.

Description of drawings

Fig. 1 is a schematic flowchart of a low-carbon scheduling method for an integrated energy system with electrical and thermal synergy provided by an embodiment of the present invention.

Detailed ways

In order to make the purpose, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below in conjunction with the drawings in the embodiments of the present invention. Obviously, the described embodiments It is only some embodiments of the present invention, but not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by persons of ordinary skill in the art without making creative efforts belong to the protection scope of the present invention.

The terms "first", "second", "third", "fourth", etc. (if any) in the description and claims of the present invention and the above drawings are used to distinguish similar objects and not necessarily Describe a specific order or sequence. It is to be understood that the data so used are interchangeable under appropriate circumstances such that the embodiments of the invention described herein can be practiced in sequences other than those illustrated or described herein.

It should be understood that in various embodiments of the present invention, the sequence numbers of the processes do not mean the order of execution, and the execution order of the processes should be determined by their energy supply and internal logic, rather than by the embodiments of the present invention. The implementation process constitutes any limitation.

It should be understood that in the present invention, "comprising" and "having" and any variations thereof are intended to cover a non-exclusive inclusion, for example, a process, method, system, product or device comprising a series of steps or units is not necessarily limited to Those steps or elements are not explicitly listed, but may include other steps or elements not explicitly listed or inherent to the process, method, product or apparatus.

It should be understood that in the present invention, "plurality" means two or more. "And/or" is just an association relationship describing associated objects, which means that there can be three kinds of relationships, for example, A and/or B, which can mean: A exists alone, A and B exist at the same time, and B exists alone. Condition. The character "/" generally indicates that the contextual objects are an "or" relationship. "Includes A, B and C", "Includes A, B, C" means that A, B, and C are all included, "includes A, B, or C" means includes one of A, B, and C, "Containing A, B and/or C" means containing any 1 or any 2 or 3 of A, B and C.

It should be understood that in the present invention, "B corresponding to A", "B corresponding to A", "A corresponding to B" or "B corresponding to A" means that B is associated with A, and according to A It is possible to determine B. Determining B from A does not mean determining B from A alone, B can also be determined from A and/or other information. The matching between A and B means that the similarity between A and B is greater than or equal to a preset threshold.

Depending on the context, "if" as used herein may be interpreted as "at" or "when" or "in response to determining" or "in response to detecting".

The technical solution of the present invention will be described in detail below with specific embodiments. The following specific embodiments may be combined with each other, and the same or similar concepts or processes may not be repeated in some embodiments.

Referring to Fig. 1, it is a schematic flowchart of a low-carbon scheduling method for an integrated energy system with electrical and thermal coordination provided by an embodiment of the present invention. The low-carbon scheduling method for an integrated energy system with electrical and thermal coordination includes S1-S5:

S1. Based on the equipment energy supply structure diagram, the electrical and thermal energy supply equipment in the target area is obtained as the equipment to be screened, and the equipment to be screened is screened in different dimensions according to the equipment screening specifications to obtain multiple target collaborative equipment.

Wherein, the target area may be an industrial park, or other types of areas, such as administrative districts. It is understandable that there are many energy-consuming equipment in the target area, such as boilers, street lamps, heating pipes and other equipment. This scheme will use the equipment energy supply structure diagram to make statistics on the electrical and heat energy supply equipment in the target area, and get There are multiple devices to be screened, and the devices to be screened will be processed in accordance with the corresponding policies.

When screening in this solution, the equipment to be screened will be screened in different dimensions according to the equipment screening specifications to obtain multiple target collaborative devices.

In some embodiments, S1 (acquiring electrical and thermal energy supply equipment in the target area as equipment to be screened based on the equipment energy supply structure diagram, and screening target collaborative equipment according to equipment screening specifications in different dimensions to obtain multiple target collaborative equipment) includes S11-S13:

S11. Determine the electrical and heat energy supply equipment as the equipment to be screened in the equipment energy supply structure diagram, and obtain input devices and output devices respectively corresponding to the equipment to be screened.

It is worth mentioning that the equipment energy supply structure diagram has energy-consuming equipment in the target area and the connection relationship between energy-consuming equipment. For example, the input equipment of the boiler can be mains equipment and gas equipment, and the output equipment can be heating pipes. The energy supply structure diagram of the equipment will have the above data corresponding to the energy consumption equipment.

S12. If the input device is a single fixed device, obtain the connection relationship of all output devices according to the device energy supply structure diagram. If it is judged that all the output devices obtained are only connected to the device to be screened, then the Connected input devices and output devices are culled.

It can be understood that if the input device is a single fixed device, it means that the device to be screened has only one form of energy consumption, for example, it only consumes mains electricity or gas. At this point, this solution will find all the output devices of the device to be screened. If all the output devices obtained are only connected to the device to be screened, it means that this energy-consuming line is single and cannot participate in the subsequent coordinated adjustment. The corresponding devices to be screened and the connected input devices and output devices are eliminated.

Exemplarily, the input device of the storage battery is only a single mains device A, and its output device has a street lamp, but the street lamp is not connected to other devices to be screened. At this time, this scheme will combine the mains device A (input device), Devices to be screened) and street lamps (output devices) are all deleted.

S13, counting all un-eliminated devices to be screened as energy supply coordination devices, counting all output devices connected to energy supply coordination devices as energy utilization coordination devices, and obtaining target coordination according to the energy supply coordination devices and energy utilization coordination devices equipment.

It is understandable that after some uncoordinated devices are deleted, this solution will count all the devices to be screened that have not been eliminated as energy supply coordination devices, and at the same time count all output devices connected to energy supply coordination devices as energy consumption collaborative equipment.

After obtaining the energy supply coordination equipment and the energy consumption coordination equipment, combine the energy supply coordination equipment and the energy consumption coordination equipment to obtain the target coordination equipment.

S2. Obtain the electrical thermal data in the target area, and filter the electrical thermal data according to different dimensions according to the data screening specifications to obtain multiple energy sequence lists.

This program will first count the electrical and thermal data in the target area, and then filter the electrical and thermal data in different dimensions according to the data screening specifications to obtain multiple energy sequence tables. For the specific screening scheme, see below.

In some embodiments, S2 (obtain electrical and thermal data in the target area, and filter the electrical and thermal data according to data screening specifications in different dimensions to obtain multiple energy sequence lists) includes S21-S22:

S21. Acquire the electrical thermal data corresponding to all the equipment in the preset time period by taking the equipment in the target area as a unit, and the electrical thermal data includes electrical thermal information corresponding to multiple sub-time periods.

It is worth mentioning that when the program conducts statistics on electrical and thermal data, it will use equipment as a unit for statistics.

At the same time, this solution will also obtain the electrical and thermal information corresponding to the equipment in multiple sub-time periods. For example, if a day is taken as a unit and an hour is a sub-time period, then this solution will obtain electrical and thermal information corresponding to 24 sub-time periods of the equipment.

S22. Obtain the electrical thermal information corresponding to the average period according to the electrical thermal information corresponding to multiple sub-time periods, generate an energy sequence table according to the electrical thermal information corresponding to the average period, and delete the electrical thermal information corresponding to all sub-time periods.

After obtaining the electrical thermal information corresponding to multiple sub-time periods, this scheme will calculate multiple electrical thermal information to obtain the electrical thermal information corresponding to the average period. For example, one month's data can be counted. For the electrical heat information from 12:00-13:00, the average value of the electrical heat information from 12:00-13:00 in a month can be used to calculate the corresponding 12: Electrical thermal information from 00-13:00.

After obtaining 24 electrical thermal information, this scheme can generate an energy sequence table based on the electrical thermal information corresponding to the average period, and remove the electrical thermal information corresponding to all sub-time periods. It can be understood that the energy sequence table has the average value information corresponding to each time period, that is, the electric heat information after the average calculation.

S3. Determine the target cooperative equipment with multi-energy conversion as the fusion corresponding equipment, and the target cooperative equipment without multi-energy conversion as the fixed corresponding equipment, and determine the energy sequence list corresponding to each fusion corresponding equipment and fixed corresponding equipment as energy input data.

This plan will determine the target cooperative equipment with multi-energy conversion as the fusion corresponding equipment, and the target cooperative equipment without multi-energy conversion as the fixed corresponding equipment. After obtaining the fusion corresponding equipment and fixed corresponding equipment, the energy sequence list corresponding to each fusion corresponding equipment and fixed corresponding equipment will be determined as energy input data.

In some embodiments, S3 (determine the target coordination device with multi-energy conversion as the fusion corresponding device, the target coordination device without multi-energy conversion as the fixed corresponding device, and determine the corresponding to each fusion corresponding device and fixed corresponding device Energy sequence table generates energy input data) including S31-S33:

S31. Determine an energy supply coordination device with multi-energy conversion as the first energy supply device, and determine an energy supply coordination device without multi-energy conversion as the second energy supply device.

For example, for the energy supply cooperative equipment boiler, it can use electricity or gas, so it is the first energy supply equipment with multi-energy conversion. For another example, for the storage battery of the energy supply cooperation equipment, it can only use electricity, so it is the second energy supply equipment without multi-energy conversion.

S32. Determine an energy-using coordinated device with multi-energy conversion as the first energy-using device, and determine an energy-using coordinated device without multi-energy conversion as the second energy-using device.

Different from step S31, step S32 classifies energy supply equipment, while this step classifies energy consuming equipment. In this plan, energy-using coordinated equipment with multi-energy conversion will be determined as the first energy-using equipment, and energy-using coordinated equipment without multi-energy conversion will be determined as the second energy-using equipment.

S33, the fusion corresponding equipment includes the first energy supply equipment or the first energy consumption equipment, the fixed corresponding equipment includes the second energy supply equipment or the second energy consumption equipment, and determine the first energy supply equipment and the second energy supply equipment The energy sequence table corresponding to the first energy-consuming equipment and the second energy-consuming equipment generates energy input data.

After obtaining the first energy supply equipment, the second energy supply equipment, the first energy consuming equipment and the second energy consuming equipment, this program will count the first energy supply equipment, the second energy supply equipment, the first energy 2. The energy sequence table corresponding to the energy-using equipment generates energy input data. That is, the present invention will make statistics on the energy sequence lists of all the first energy supply equipment, the second energy supply equipment, the first energy consumption equipment and the second energy consumption equipment to obtain the final energy input data.

S4. Construct a corresponding low-carbon dispatch model, input energy input data into the low-carbon dispatch model for data processing, and obtain a low-carbon dispatch strategy corresponding to the target area.

In order to carry out low-carbon dispatching, this scheme is equipped with a low-carbon dispatching model, which is used to input energy input data into the low-carbon dispatching model for data processing, and obtain the corresponding low-carbon dispatching strategy of the target area, so that the energy consumption in the target area can reach a low carbon state.

In some embodiments, S4 (construct a corresponding low-carbon dispatch model, input energy input data into the low-carbon dispatch model for data processing, and obtain a low-carbon dispatch strategy corresponding to the target area) includes A41-A45:

A41. Construct a corresponding low-carbon scheduling model. The low-carbon scheduling model determines the first energy supply device or the second energy supply device connected to the second energy-consuming device based on the equipment energy supply structure diagram.

First, the low-carbon scheduling model of this scheme will use the equipment energy supply structure diagram to determine the first energy supply equipment or the second energy supply equipment connected to the second energy-consuming equipment. It can be understood that the energy supply device of the second energy-consuming device is single, for example, it can only be powered by electricity.

A42. Add a first dispatch label to the determined first energy supply device or second energy supply device, the first dispatch label has the identity information of the second energy use device and the energy sequence list corresponding to the second energy use device .

After finding the corresponding first energy supply equipment or second energy supply equipment, this solution will add the first scheduling label corresponding to the second energy supply equipment to the first energy supply equipment or the second energy supply equipment to mark the energy supply equipment Provide energy for the corresponding second energy-consuming equipment.

Wherein, the first scheduling tag contains the identity information of the second energy-consuming device and the energy sequence list corresponding to the second energy-using device.

A43. The low-carbon scheduling model determines the first energy supply equipment and/or the second energy supply equipment connected to the first energy consumption equipment based on the equipment energy supply structure diagram.

It can be understood that the first energy-consuming device is an energy-consuming device with various forms of energy supply, for example, a boiler, which can be powered by commercial power or gas. At this time, the low-carbon scheduling model of this solution will use the equipment energy supply structure diagram to determine the first energy supply equipment and/or the second energy supply equipment connected to the first energy-consuming equipment.

A44, if the sum of the first energy supply equipment and/or the second energy supply equipment is 2, compare the first energy supply equipment with the second energy supply equipment, and determine The equipment with small carbon emissions in the time period is used as the third energy supply equipment.

If the sum of the first energy supply equipment and/or the second energy supply equipment is 2, it means that there is an optional energy supply equipment. At this time, this solution will compare the first energy supply equipment and the second energy supply equipment to determine For the first energy-consuming equipment, the equipment with small carbon emissions in different sub-time periods is used as the third energy supply equipment.

Exemplarily, the first energy-using device A has a first energy-supplying device B and a second energy-supplying device C, and the first energy-using device A corresponds to a sub-time period of 12:00-13:00, the first energy-supplying device The carbon emission of B is smaller than that of the second energy supply equipment C. At this time, this scheme will use the first energy supply equipment B as the third energy supply equipment of the first energy consumption equipment A during 12:00-13:00.

A45. The low-carbon scheduling model generates second scheduling labels of different sub-time periods and adds them to the corresponding third energy supply equipment. The second scheduling label has the identity information of the first energy-consuming equipment, the corresponding sub-time period Electrical Thermal Information.

The low-carbon scheduling model will generate second scheduling labels of different sub-time periods and add them to the corresponding third energy supply equipment, so as to use the second scheduling label to instruct the corresponding third energy supply equipment to supply energy for the first energy-consuming equipment can achieve a low-carbon state.

On the basis of the foregoing embodiments, it also includes:

If the sum of the first energy supply equipment or the second energy supply equipment is greater than 2, then all the first energy supply equipment and the second energy supply equipment are compared, and it is determined that for the first energy supply equipment in different sub-time periods carbon emissions.

It can be understood that if the sum of the first energy supply equipment or the second energy supply equipment is greater than 2, for example, there are 3, at this time, this solution will compare all the first energy supply equipment and the second energy supply equipment, Carbon emissions for the first energy-consuming equipment in different sub-time periods are determined.

Among them, when calculating carbon emissions, the existing technology can be used for calculation. For example, the energy supply equipment needs to supply 1000 degrees of mains power in the sub-time period of 12:00-13:00, which can be calculated by combining the carbon factor of electricity. Carry out carbon emission conversion. At the same time, the energy supplied by the 1000-kWh city electricity can be converted into the amount of gas, and then the carbon emissions generated by the consumption of gas can be converted. The calculation of carbon emissions here is a prior art and will not be repeated here.

The low-carbon scheduling model generates the first scheduling label group corresponding to the first energy supply equipment or the second energy supply equipment, and according to the carbon emissions corresponding to the first energy supply equipment or the second energy supply equipment The second scheduling tags are sorted, and the corresponding second scheduling tags are respectively added to the corresponding first energy supply device or the second energy supply device.

After obtaining the carbon emissions, this scheme will combine the carbon emissions to sort the second scheduling tags of the first scheduling tag group in ascending order, so that the ones with less carbon emissions are sorted first, and the ones with larger carbon emissions are sorted last. Then add the corresponding second scheduling label to the corresponding first energy supply device or the second energy supply device respectively.

It should be noted that the above scheme is a scheduling strategy for energy-consuming equipment, and the following scheme is a scheduling strategy for energy-supplying equipment.

In some embodiments, S4 (the construction of a corresponding low-carbon dispatch model, inputting energy input data into the low-carbon dispatch model for data processing, and obtaining a low-carbon dispatch strategy corresponding to the target area) includes S41-S44:

S41. The low-carbon scheduling model determines multiple input devices connected to the first energy supply device based on the device energy supply structure diagram.

First, the low-carbon scheduling model of this solution will use the equipment energy supply structure diagram to determine multiple input devices connected to the first energy supply equipment.

S42. Calculate the carbon emissions corresponding to the multiple input devices when the first energy supply device is in the working state of the corresponding sub-time period, and add the third scheduling label to the input devices corresponding to the input devices with less carbon emissions.

After obtaining multiple input devices, this program will calculate the carbon emissions corresponding to the multiple input devices in the working state of the first energy supply device in the corresponding sub-time period, and then calculate the corresponding input The device adds a third scheduling tag.

It is worth mentioning that the above solution is for the case where there are two input devices.

S43, if the multiple input devices are greater than 2, generate a second scheduling tag group corresponding to the multiple input devices, and sort the third scheduling tags of the second scheduling tag group according to the carbon emissions corresponding to each input device, Corresponding third scheduling tags are respectively added to corresponding input devices, and each third scheduling tag has corresponding sequence information.

It can be understood that if the number of input devices is greater than 2, for example, there are 3, at this time, this solution will sort the third scheduling tags of the second scheduling tag group in combination with the carbon emissions corresponding to each input device, and then Corresponding third scheduling tags are respectively added to corresponding input devices, and each third scheduling tag has corresponding sequence information.

Among them, when sorting, it can be sorted in ascending order according to the carbon emissions, so that the ones with less carbon emissions are sorted first, and the ones with larger carbon emissions are sorted last, and then the corresponding input devices are added to the corresponding third Scheduling tab.

S44. The low-carbon scheduling model generates corresponding low-carbon scheduling strategies according to all the first scheduling labels, the second scheduling labels, and the third scheduling labels.

The low-carbon scheduling model of this scheme will generate corresponding low-carbon scheduling strategies based on all the first scheduling label, the second scheduling label and the third scheduling label. That is, equipment with less carbon emissions is selected for energy scheduling, so that the overall carbon emissions in the target area are lower.

S5. Obtain the corresponding energy demand information in the target area in real time, and generate a control strategy for the fusion corresponding equipment and the fixed corresponding equipment according to the energy demand information and the low-carbon dispatching strategy.

This solution will obtain the corresponding energy demand information in the target area in real time, for example, what equipment needs to be started, and then generate a control strategy for the fusion corresponding equipment and fixed corresponding equipment according to the energy demand information and low-carbon scheduling strategy.

In some embodiments, S5 (obtaining the corresponding energy demand information in the target area in real time, and generating a control strategy for the fusion corresponding equipment and the fixed corresponding equipment according to the energy demand information and low-carbon scheduling strategy) includes S51-S53:

S51, obtain the preset working time of all the first energy-consuming equipment and the second energy-consuming equipment in the target area, and determine that the current time is close to the preset working time of all the first energy-consuming equipment and the second energy-consuming equipment, and will work The third energy-using equipment and the fourth energy-consuming equipment.

First, this solution obtains the preset working hours of all the first energy-consuming equipment and the second energy-consuming equipment in the target area, for example, the first energy-consuming equipment A needs to work between 12:00-13:00. Then, this solution determines the third energy-consuming equipment and the fourth energy-consuming equipment that will work near the current moment in the preset working time of all the first energy-consuming equipment and the second energy-consuming equipment.

S52. Determine the first energy supply device and/or the second energy supply device corresponding to the third energy use device and the fourth energy supply device, according to the first energy supply device and/or the second energy supply device configured The scheduling label and the second scheduling label determine the target energy supply equipment that supplies energy to the third energy consuming equipment and the fourth energy consuming equipment.

This scheme will determine the first energy supply equipment and/or the second energy supply equipment corresponding to the third energy consumption equipment and the fourth energy consumption equipment, that is to say, it is necessary to provide power supply for the third energy consumption equipment and the fourth energy consumption equipment capable equipment to determine what equipment needs to be activated for energy supply.

After obtaining the corresponding first energy supply equipment and/or second energy supply equipment, this solution will use the first scheduling label and the second scheduling label configured by the first energy supply equipment and/or the second energy supply equipment to determine the The target energy supply equipment supplied by the third energy consumption equipment and the fourth energy consumption equipment.

Wherein, according to the first scheduling label and the second scheduling label configured by the first energy supplying equipment and/or the second energy supplying equipment, the target energy supply for the third energy using equipment and the fourth energy using equipment is determined. Equipment, including S521-S523:

S521. Determine the load information of the third energy consuming equipment and the fourth energy consuming equipment corresponding to the first energy supply equipment and/or the second energy supply equipment, if the first energy supply equipment and/or the second energy supply equipment meet the requirements If the above load information is used, the first energy supply device and/or the second energy supply device are controlled based on the priority order of the first scheduling label and the second scheduling label, and energy is supplied to the third energy consumption equipment and the fourth energy consumption equipment.

It should be noted that this scheme not only considers carbon emissions, but also considers load information for comprehensive scheduling.

This scheme will obtain the load information of the third energy-using equipment and the fourth energy-consuming equipment corresponding to the first energy supply equipment and/or the second energy supply equipment, if the first energy supply equipment and/or the second energy supply equipment meet Load information, indicating that the energy supply demand can be met, then use the priority order of the first scheduling label and the second scheduling label to control the first energy supply equipment and/or the second energy supply equipment, and for the third energy-consuming equipment and the fourth energy-consuming equipment The energy supply of energy equipment is enough, that is, the energy supply equipment with low carbon emission is prioritized for energy supply, so as to reduce the carbon emission of the target area.

S522. If the first energy supply equipment and/or the second energy supply equipment do not satisfy the load information, transfer the third energy consumption equipment from the current first energy supply equipment or the second energy supply equipment to other first energy supply equipment. The energy supply device or the second energy supply device supplies energy.

If the first energy supply equipment and/or the second energy supply equipment do not meet the load information, the third energy supply equipment is transferred from the current first energy supply equipment or the second energy supply equipment to other first energy supply equipment or The second energy supply device supplies energy.

For example, it is initially determined that the first energy supply equipment A is supplying energy, but the first energy supply equipment A cannot meet the load demand, then the third energy consumption equipment will be transferred from the current first energy supply equipment A at this time To supply energy to other first energy supply equipment B or second energy supply equipment C.

S523. Determine target energy supply equipment that supplies energy to the third energy consumption equipment and the fourth energy consumption equipment.

This scheme will determine the target energy supply equipment that supplies energy to the third energy consumption equipment and the fourth energy consumption equipment.

S53. Determine the target input device corresponding to the target energy supply device according to the third scheduling label configured on the input device.

In this solution, the target input device corresponding to the target energy supply device will be determined in combination with the third scheduling tag configured on the input device.

In some embodiments, S53 (determine the target input device corresponding to the target energy supply device according to the third scheduling tag configured on the input device) includes S531-S535:

S531. Determine all input devices connected to the target energy supply device.

First, this program will get all input devices connected to the target power supply device.

S532. If the number of input devices is 1, use one corresponding input device as a target input device.

If the input device is 1, then there is no need to make a judgment. At this time, this solution only needs to use one corresponding input device as the target input device.

S533. If the number of input devices is greater than 1, determine the corresponding input device as the target input device according to the order of the second scheduling tags in the second scheduling tag group.

If the input device is greater than 1, then this solution will select according to the order of the second scheduling tag in the second scheduling tag group, find the device with low carbon emissions as the input device, and finally determine the corresponding input device as the target input device.

S534. If the load information of the target input device does not meet the requirements, connect the first energy supply device connected to the target input device that does not meet the requirements with other connected input devices.

If the load information of the target input device does not meet the requirements, the first energy supply device connected to the target input device that does not meet the requirements is connected to other connected input devices.

S535. Determine the input device that supplies energy to the first energy supply device and the second energy supply device as a target input device.

Finally, in this solution, the input device that supplies power to the first power supply device and the second power supply device will be determined as the target input device.

The embodiment of the present invention also provides a low-carbon dispatching system of an integrated energy system with synergy between electricity and heat. The low-carbon dispatch system of an integrated energy system with synergy between electricity and heat includes:

The screening module is used to obtain the electrical and thermal energy supply equipment in the target area as the equipment to be screened based on the equipment energy supply structure diagram, and screen the equipment to be screened according to the equipment screening specifications in different dimensions to obtain multiple target collaborative equipment;

The sequence table module is used to obtain the electrical thermal data in the target area, and filter the electrical thermal data according to different dimensions according to the data screening specifications to obtain multiple energy sequence tables;

The classification module is used to determine the target cooperative equipment with multi-energy conversion as the fusion corresponding equipment, and the target cooperative equipment without multi-energy conversion as the fixed corresponding equipment, and determine the energy sequence list corresponding to each fusion corresponding equipment and fixed corresponding equipment as energy input data;

The strategy module is used to construct the corresponding low-carbon dispatching model, input energy input data into the low-carbon dispatching model for data processing, and obtain the corresponding low-carbon dispatching strategy for the target area;

The scheduling module is used to obtain the corresponding energy demand information in the target area in real time, and generate a control strategy for the fusion corresponding equipment and the fixed corresponding equipment according to the energy demand information and the low-carbon scheduling strategy.

The present invention also provides a storage medium, where a computer program is stored in the storage medium, and the computer program is used to implement the methods provided by the above-mentioned various implementation modes when executed by a processor.

Wherein, the storage medium may be a computer storage medium or a communication medium. Communication media includes any medium that facilitates transfer of a computer program from one place to another. Computer storage media can be any available media that can be accessed by a general purpose or special purpose computer. For example, a storage medium is coupled to the processor such the processor can read information from, and write information to, the storage medium. Of course, the storage medium may also be a component of the processor. The processor and the storage medium may be located in application specific integrated circuits (Application Specific Integrated Circuits, ASIC for short). Additionally, the ASIC may be located in the user equipment. Of course, the processor and the storage medium can also exist in the communication device as discrete components. The storage media may be read only memory (ROM), random access memory (RAM), CD-ROM, magnetic tapes, floppy disks, and optical data storage devices, among others.

The present invention also provides a program product, which includes execution instructions, and the execution instructions are stored in a storage medium. At least one processor of the device may read the execution instruction from the storage medium, and the at least one processor executes the execution instruction so that the device implements the methods provided in the foregoing various implementation manners.

In the above embodiment of the terminal or server, it should be understood that the processor may be a central processing unit (English: Central Processing Unit, CPU for short), and may also be other general-purpose processors, digital signal processors (English: Digital Signal Processor , referred to as: DSP), application specific integrated circuit (English: Application SpecificIntegrated Circuit, referred to as: ASIC) and so on. A general-purpose processor may be a microprocessor, or the processor may be any conventional processor, or the like. The steps of the method disclosed in conjunction with the present invention can be directly implemented by a hardware processor, or implemented by a combination of hardware and software modules in the processor.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solutions of the present invention, rather than limiting them; although the present invention has been described in detail with reference to the foregoing embodiments, those of ordinary skill in the art should understand that: It is still possible to modify the technical solutions described in the foregoing embodiments, or perform equivalent replacements for some or all of the technical features; and these modifications or replacements do not make the essence of the corresponding technical solutions deviate from the technical solutions of the various embodiments of the present invention. scope.

Claims (10)

1. The low-carbon scheduling method of the integrated energy system with electric and heat synergy, characterized in that it includes: Based on the equipment energy supply structure diagram, the electrical and thermal energy supply equipment in the target area is obtained as the equipment to be screened, and the equipment to be screened is screened according to different dimensions according to the equipment screening specifications to obtain multiple target collaborative equipment; Obtain the electrical and thermal data in the target area, and filter the electrical and thermal data according to different dimensions according to the data screening specifications to obtain multiple energy sequence lists; Determine the target cooperative equipment with multi-energy conversion as the fusion corresponding equipment, and the target cooperative equipment without multi-energy conversion as the fixed corresponding equipment, and determine the energy sequence list corresponding to each fusion corresponding equipment and fixed corresponding equipment as energy input data; Construct the corresponding low-carbon dispatching model, input energy input data into the low-carbon dispatching model for data processing, and obtain the corresponding low-carbon dispatching strategy for the target area; Obtain the corresponding energy demand information in the target area in real time, and generate control strategies for fusion corresponding equipment and fixed corresponding equipment according to energy demand information and low-carbon dispatching strategies. 2. The low-carbon dispatching method for an integrated energy system based on electrical and thermal synergy according to claim 1, characterized in that, The electrical and thermal energy supply equipment in the target area is obtained based on the equipment energy supply structure diagram as the equipment to be screened, and the target collaborative equipment is screened in different dimensions according to the equipment screening specifications to obtain multiple target collaborative equipment, including: Determine the electrical and thermal energy supply equipment as the equipment to be screened in the equipment energy supply structure diagram, and obtain the input equipment and output equipment corresponding to the equipment to be screened; If the input device is a single fixed device, then obtain the connection relationship of all output devices according to the device energy supply structure diagram, if it is judged that all the output devices obtained are only connected to the device to be screened, then the Input device and output device culling; Count all un-rejected devices to be screened as energy-supply coordination devices, count all output devices connected to energy-supply coordination devices as energy-use coordination devices, and obtain target coordination devices according to the energy-supply coordination devices and energy-use coordination devices. 3. The low-carbon dispatching method for an integrated energy system based on electric and thermal synergy according to claim 2, characterized in that, The acquisition of electrical and thermal data in the target area is performed, and multiple energy sequence tables are obtained by filtering the electrical and thermal data according to the data screening specifications according to different dimensions, including: Obtaining the electrical thermal data corresponding to all the equipment in the preset time period by taking the equipment in the target area as a unit, and the electrical thermal data includes electrical thermal information corresponding to multiple sub-time periods; According to the electrical thermal information corresponding to multiple sub-time periods, the electrical thermal information corresponding to the average period is obtained, and the energy sequence table is generated according to the electrical thermal information corresponding to the average period, and the electrical thermal information corresponding to all sub-time periods is eliminated. 4. The low-carbon scheduling method for an integrated energy system based on electric and thermal synergy according to claim 3, characterized in that, Determining the target cooperative equipment with multi-energy conversion as the fusion corresponding equipment, and the target coordination equipment without multi-energy conversion as the fixed corresponding equipment, determining the energy sequence list corresponding to each fusion corresponding equipment and fixed corresponding equipment to generate energy input data, including: Determine the energy supply coordination equipment with multi-energy conversion as the first energy supply equipment, and determine the energy supply coordination equipment without multi-energy conversion as the second energy supply equipment; Determine the energy-using coordinated equipment with multi-energy conversion as the first energy-using equipment, and determine the energy-using coordinated equipment without multi-energy conversion as the second energy-using equipment; The fusion corresponding equipment includes the first energy supply equipment or the first energy consuming equipment, the fixed corresponding equipment includes the second energy supply equipment or the second energy consuming equipment, and it is determined that the first energy supply equipment, the second energy supply equipment, the second energy supply equipment The energy sequence tables corresponding to the first energy-consuming equipment and the second energy-consuming equipment generate energy input data. 5. The low-carbon dispatching method for an integrated energy system based on electric and thermal synergy according to claim 4, characterized in that, The construction of the corresponding low-carbon dispatching model, input energy input data into the low-carbon dispatching model for data processing, and obtain the corresponding low-carbon dispatching strategy of the target area, including: Construct a corresponding low-carbon scheduling model, and the low-carbon scheduling model determines the first energy supply equipment or the second energy supply equipment connected to the second energy-consuming equipment based on the equipment energy supply structure diagram; Adding a first scheduling tag to the determined first energy supply device or second energy supply device, the first scheduling tag has the identity information of the second energy consuming device and the energy sequence list corresponding to the second energy consuming device; The low-carbon scheduling model determines the first energy supply equipment and/or the second energy supply equipment connected to the first energy-consuming equipment based on the equipment energy supply structure diagram; If the sum of the first energy supply device and/or the second energy supply device is 2, then compare the first energy supply device with the second energy supply device, and determine that for the first energy supply device in different sub-time periods Equipment with low carbon emissions is used as the third energy supply equipment; The low-carbon scheduling model generates second scheduling labels of different sub-time periods and adds them to the corresponding third energy supply equipment. The second scheduling label has the identity information of the first energy-consuming equipment, the electrical thermal information. 6. The low-carbon scheduling method for an integrated energy system based on electric and thermal synergy according to claim 5, further comprising: If the sum of the first energy supply equipment or the second energy supply equipment is greater than 2, then all the first energy supply equipment and the second energy supply equipment are compared, and it is determined that for the first energy supply equipment in different sub-time periods carbon emissions; The low-carbon scheduling model generates the first scheduling label group corresponding to the first energy supply equipment or the second energy supply equipment, and according to the carbon emissions corresponding to the first energy supply equipment or the second energy supply equipment The second scheduling tags are sorted, and the corresponding second scheduling tags are respectively added to the corresponding first energy supply device or the second energy supply device. 7. The low-carbon dispatching method for an integrated energy system based on electrical and thermal synergy according to claim 6, characterized in that, The construction of the corresponding low-carbon dispatching model, input energy input data into the low-carbon dispatching model for data processing, and obtain the corresponding low-carbon dispatching strategy of the target area, including: The low-carbon scheduling model determines multiple input devices connected to the first energy supply device based on the device energy supply structure diagram; Calculate the carbon emissions of multiple input devices corresponding to the first energy supply device in the working state of the corresponding sub-time period, and add the third scheduling label to the input devices corresponding to the input devices with less carbon emissions; If the number of input devices is greater than 2, then generate the second scheduling tag group corresponding to the multiple input devices, sort the third scheduling tags of the second scheduling tag group according to the carbon emissions corresponding to each input device, and sort the corresponding Add corresponding third scheduling tags to the input devices respectively, and each third scheduling tag has corresponding sequence information; The low-carbon scheduling model generates corresponding low-carbon scheduling strategies according to all the first scheduling labels, the second scheduling labels and the third scheduling labels. 8. The low-carbon dispatching method for an integrated energy system based on electrical and thermal synergy according to claim 7, characterized in that, The real-time acquisition of corresponding energy demand information in the target area, and generation of control strategies for fusion corresponding equipment and fixed corresponding equipment according to energy demand information and low-carbon scheduling strategies include: Obtain the preset working time of all the first energy-consuming equipment and the second energy-consuming equipment in the target area, and determine the first energy-consuming equipment that will work near the current moment in the preset working time of all the first energy-consuming equipment and the second energy-consuming equipment Three energy-using equipment and fourth energy-using equipment; Determining the first energy supply device and/or the second energy supply device corresponding to the third energy use device and the fourth energy use device, according to the first scheduling label configured by the first energy supply device and/or the second energy supply device , the second scheduling label determines the target energy supply equipment that supplies energy to the third energy consumption equipment and the fourth energy consumption equipment; The target input device corresponding to the target energy supply device is determined according to the third scheduling tag configured on the input device. 9. The low-carbon scheduling method for an integrated energy system based on electrical and thermal synergy according to claim 8, characterized in that, determining the target energy supply equipment for supplying energy to the third energy-consuming equipment and the fourth energy-consuming equipment according to the first scheduling label and the second scheduling label configured by the first energy supply equipment and/or the second energy supply equipment, include: Determining the load information of the third energy-using equipment and the fourth energy-consuming equipment corresponding to the first energy supplying equipment and/or the second energy supplying equipment, if the first energy supplying equipment and/or the second energy supplying equipment meet the load information, based on the priority order of the first scheduling label and the second scheduling label, the first energy supply device and/or the second energy supply device are controlled, and the third energy consumption device and the fourth energy consumption device are supplied with energy; If the first energy supply equipment and/or the second energy supply equipment do not meet the load information, the third energy supply equipment is transferred from the current first energy supply equipment or the second energy supply equipment to other first energy supply equipment equipment or a second energy supply device; Determine the target energy supply equipment that supplies energy to the third energy consumption equipment and the fourth energy consumption equipment. 10. The low-carbon dispatching method for an integrated energy system based on electrical and thermal synergy according to claim 9, characterized in that, The determining the target input device corresponding to the target energy supply device according to the third scheduling label configured by the input device includes: Identify all input devices connected to the target energy supply device; If the number of input devices is 1, take one corresponding input device as the target input device; If the number of input devices is greater than 1, then determine the corresponding input device as the target input device according to the order of the second scheduling tag in the second scheduling tag group; If the load information of the target input device does not meet the requirements, the first energy supply device of the target input device that does not meet the requirements is connected to other connected input devices; The input device that supplies power to the first power supply device and the second power supply device is determined as the target input device.

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