Intelligent power distribution method, device and equipment based on wind power generation and storage medium

By using intelligent power distribution methods, wind power can be selectively used or stored based on the power supply conditions of the power grid, thus solving the problem of wasted wind power and improving power utilization and power supply stability.

CN115173407BActive Publication Date: 2026-06-05HANGZHOU GUODIAN ELECTRIC POWER TECH DEV CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
HANGZHOU GUODIAN ELECTRIC POWER TECH DEV CO LTD
Filing Date
2022-07-26
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

In existing technologies, wind power is wasted when the main power generation can meet the electricity demand, resulting in low power utilization.

Method used

By using intelligent power distribution methods, wind power can be selectively used based on the power supply status of the power grid, and can be promptly connected to the power grid for auxiliary power supply or storage, thereby avoiding power supply anomalies and improving power utilization.

Benefits of technology

When power consumption fluctuates in the power grid, wind power generation can be utilized or stored in a timely manner to ensure the stability and efficiency of power supply and reduce waste.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

The application relates to an intelligent power distribution method, device and equipment based on wind power generation and a storage medium, and belongs to the technical field of power distribution.The method comprises the following steps: calculating the power supply and consumption difference between the current collection period power consumption and the power supply threshold; judging whether the power supply and consumption difference is not less than a preset first auxiliary power supply threshold; if the power supply and consumption difference is not less than the preset first auxiliary power supply threshold, auxiliary power supply is performed; if the power supply and consumption difference is less than the preset first auxiliary power supply threshold, the last power consumption of the current power supply area is acquired; the power consumption difference between the current power consumption and the last power consumption is calculated; judging whether the power consumption difference is not less than a preset second auxiliary power supply threshold; if the power consumption difference is not less than the second auxiliary power supply threshold, auxiliary power supply is performed; and if the power consumption difference is less than the second auxiliary power supply threshold, the wind power generation power is stored. The application has the effect of improving the utilization rate of the wind power generation power.
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Description

Technical Field

[0001] This application relates to the technical field of power distribution, and in particular to a smart power distribution method, apparatus, equipment and storage medium based on wind power generation. Background Technology

[0002] With rapid economic development, electricity has become the most basic energy source in daily life. Electricity plays a crucial role in a country, providing irreplaceable support for industrial and agricultural production, national defense, and people's livelihoods. Its applications are extremely widespread; in modern industry, agriculture, and other sectors of the national economy, electricity serves as the primary power source.

[0003] To ensure basic public services, electricity is generally supplied by a unified power grid. In most areas, thermal power generation is the main source of power. However, there are situations where thermal power generation cannot meet the demand. To ensure normal power supply, wind power generation is usually added as an auxiliary power source to thermal power generation. When the main power generation can meet the demand, the electricity generated by wind power generation will be wasted. Summary of the Invention

[0004] In order to improve the utilization rate of electricity generated by wind power generation, this application provides a smart power distribution method, device, equipment and storage medium based on wind power generation.

[0005] Firstly, this application provides a smart power distribution method based on wind power generation, employing the following technical solution:

[0006] A smart power distribution method based on wind power generation, comprising:

[0007] Obtain the current data collection period and the current power supply threshold of the power supply network for the current data collection period, and calculate the difference between the current data collection period's power consumption and the power supply threshold;

[0008] Determine whether the difference between the power supply and consumption is not less than a preset first auxiliary power supply threshold;

[0009] If the difference is less than the preset first auxiliary power supply threshold, the wind power will be connected to the power supply network for auxiliary power supply.

[0010] If the difference is not less than the preset first auxiliary power supply threshold, then the power consumption of the current power supply area in the previous collection cycle is obtained;

[0011] Calculate the difference in electricity consumption between the current data collection cycle and the previous data collection cycle;

[0012] Determine whether the difference in power consumption is not less than a preset second auxiliary power supply threshold;

[0013] If the difference in power consumption is not less than the second auxiliary power supply threshold, then the power generated by the wind power generation will be connected to the power supply network for auxiliary power supply.

[0014] If the difference in power consumption is less than the second auxiliary power supply threshold, then the power generated by the wind power generation is stored.

[0015] By adopting the above technical solution, wind power can be selectively used based on the power supply situation of the current power supply area. Before situations arise where the power consumption in the current power supply area is too high or suddenly increases or decreases, potentially causing power supply anomalies in the power supply network, the wind power can be used in a timely manner. When the power supply of the power supply network can meet the power consumption of the current power supply area, the wind power can be stored and used when the power supply network encounters problems, thereby improving the utilization rate of wind power.

[0016] Optionally, connecting the wind power generated to the power supply network for auxiliary power supply includes:

[0017] Obtain all electricity-consuming locations in the current power supply area and the electricity consumption of each location;

[0018] Arrange the power consumption of the locations in descending order of their numerical values ​​to generate a power supply sequence;

[0019] Obtain power supply rules, and provide auxiliary power supply to the power consumption site based on the power supply rules and the power supply sequence.

[0020] Optionally, after storing the electricity generated by the wind power, the method further includes:

[0021] Obtain the power supply status of the current power supply area, including normal power supply and no power supply;

[0022] When the power supply status is no power supply, obtain all power-consuming locations in the current power supply area and the power consumption type corresponding to each power-consuming location;

[0023] Obtain the power allocation rules, and supply the wind power generated at the power consumption site based on the power allocation rules and the power consumption type;

[0024] When the power supply status is normal, the power generated by the wind power generation continues to be stored.

[0025] Optionally, supplying power to the power-consuming location using the wind-generated electricity based on the power allocation rules and the power consumption type includes:

[0026] The power consumption sites are classified into levels according to a preset first-level classification rule to generate a first power supply level;

[0027] The electricity consumption type is classified into levels according to a preset second-level classification rule to generate a second power supply level;

[0028] The historical electricity consumption of the electricity consumption type is obtained, and the electricity used by the wind power generation is supplied to the electricity consumption site based on the first power supply level, the second power supply level and the historical electricity consumption of the electricity consumption type.

[0029] Optionally, the continued storage of the wind-generated electricity includes:

[0030] Obtain the current power storage capacity of the power storage system and the maximum power storage capacity of the power storage system, and calculate the difference between the current power storage capacity and the maximum storage capacity;

[0031] Determine whether the difference in storage quantity is not less than a preset storage threshold;

[0032] If the difference in storage volume is less than the preset storage threshold, then a backup power storage system is obtained, and the power generated by the wind power generation is stored in the backup power storage system.

[0033] If the difference in storage volume is not less than the preset storage threshold, then the electricity generated by the wind power generation will be stored in the current energy storage system.

[0034] Optionally, after storing the electricity generated by the wind power, the method further includes:

[0035] Obtain historical electricity consumption information and power supply strategy for the current power supply area, and supply electricity to the current power supply area using the wind power generation based on the historical electricity consumption information and the power supply strategy.

[0036] Optionally, supplying power to the current power supply area using the wind power generated based on the historical electricity consumption information and the power supply strategy includes:

[0037] Obtain the power supply load value and historical maximum power consumption value of the power supply network;

[0038] Determine whether the historical maximum electricity consumption is not less than the power supply load value;

[0039] If the historical maximum electricity consumption is not less than the power supply load value, then obtain the time period corresponding to the historical maximum electricity consumption;

[0040] Before each of the specified time periods, the power generated by the wind power generation is connected to the power supply network in advance for auxiliary power supply.

[0041] Secondly, this application provides an intelligent power distribution device based on wind power generation, which adopts the following technical solution:

[0042] A smart power distribution device based on wind power generation, comprising:

[0043] The regional electricity consumption acquisition module is used to acquire the current electricity consumption of the current acquisition period and the power supply threshold of the power supply network in the current power supply area, and to calculate the difference between the current electricity consumption and the power supply threshold.

[0044] The power supply difference judgment module is used to determine whether the difference between the power supply and consumption is not less than a preset first auxiliary power supply threshold.

[0045] The first auxiliary power supply module is used to connect the power generated by wind power generation to the power supply network for auxiliary power supply;

[0046] The previous power consumption acquisition module is used to acquire the power consumption of the current power supply area in the previous acquisition cycle;

[0047] The electricity consumption difference calculation module is used to calculate the difference between the electricity consumption in the current collection cycle and the electricity consumption in the previous collection cycle.

[0048] The power consumption difference judgment module is used to determine whether the difference in power consumption is not less than a preset second auxiliary power supply threshold.

[0049] The second auxiliary power supply module is used to connect the power generated by the wind power generation to the power supply network for auxiliary power supply;

[0050] A wind power generation storage module is used to store the electricity generated by the wind power generation.

[0051] By adopting the above technical solution, wind power can be selectively used based on the power supply situation of the current power supply area. Before situations arise where the power consumption in the current power supply area is too high or suddenly increases or decreases, potentially causing power supply anomalies in the power supply network, the wind power can be used in a timely manner. When the power supply of the power supply network can meet the power consumption of the current power supply area, the wind power can be stored and used when the power supply network encounters problems, thereby improving the utilization rate of wind power.

[0052] Thirdly, this application provides an electronic device that adopts the following technical solution:

[0053] An electronic device includes a memory and a processor, wherein the memory stores a computer program capable of being loaded by the processor and executing the intelligent power distribution method based on wind power generation as described in any of the first aspects.

[0054] Fourthly, this application provides a computer-readable storage medium, which adopts the following technical solution:

[0055] A computer-readable storage medium storing a computer program capable of being loaded by a processor and executing the intelligent power distribution method based on wind power generation as described in any of the first aspects. Attached Figure Description

[0056] Figure 1 This is a flowchart illustrating a smart power distribution method based on wind power generation provided in an embodiment of this application.

[0057] Figure 2 This is a structural block diagram of an intelligent power distribution device based on wind power generation provided in an embodiment of this application.

[0058] Figure 3 This is a structural block diagram of the electronic device provided in the embodiments of this application. Detailed Implementation

[0059] The present application will be further described in detail below with reference to the accompanying drawings.

[0060] Figure 1 This is a flowchart illustrating a smart power distribution method based on wind power generation, provided as an embodiment of this application.

[0061] like Figure 1 As shown, the main process of this method is described below (steps S101 to S108):

[0062] Step S101: Obtain the current data collection period and the current power consumption of the current power supply area and the power supply threshold of the power supply network, and calculate the power supply difference between the current power consumption and the power supply threshold.

[0063] In this embodiment, in order to ensure a continuous power supply and the accuracy of power consumption data collection, it is necessary to periodically collect the power consumption of the current power supply area. The collection period needs to be set according to actual needs, generally in minutes. If not set, the default is 5 minutes, and no specific limitation is made here.

[0064] The power supply threshold of the power supply network is the maximum power supply that the main power source in the power supply network can provide. The power supply threshold of the power supply network is calculated by subtracting the power consumption value of the current collection period from the power supply threshold. The difference between the power consumption value of the current collection period and the power supply threshold is then obtained.

[0065] Step S102: Determine whether the difference between power supply and consumption is not less than the preset first auxiliary power supply threshold.

[0066] Step S103: If the difference between power supply and demand is less than the preset first auxiliary power supply threshold, the power generated by wind power generation will be connected to the power supply network for auxiliary power supply.

[0067] In this embodiment, the preset first auxiliary power supply threshold is the maximum value used to determine whether to use wind power for auxiliary power supply based on the current power supply and the power supply threshold. The smaller the difference between power supply and consumption, the closer the current power consumption is to the power supply threshold. When the difference between power supply and consumption is less than the preset first auxiliary power supply threshold, it indicates that there is a possibility of power supply abnormality in the main power source. To ensure the normal power supply in the current power supply area, it is necessary to connect wind power to the power grid for auxiliary power supply. It should be noted that, due to the instability of wind power, to ensure the stability of auxiliary power supply, when connecting wind power to the power grid, both the currently used wind power and the stored wind power can be connected to the power grid simultaneously. If the currently used wind power is stable and can provide continuous and efficient auxiliary power supply, only the currently used wind power can be used for auxiliary power supply. If auxiliary power supply is needed but there is no currently used wind power, the stored wind power can be used directly for auxiliary power supply. The specific auxiliary power supply method needs to be selected according to the actual situation and is not specifically limited here. The preset first auxiliary power supply threshold needs to be set according to the actual situation, and no specific limit is made here.

[0068] For step S103, obtain all the power-consuming locations in the current power supply area and the power consumption of each location; sort the power consumption of the locations in descending order of the values ​​to generate a power supply sequence; obtain the power supply rules, and provide auxiliary power supply to the power-consuming locations based on the power supply rules and the power supply sequence.

[0069] In this embodiment, the locations using electricity include residential areas, hospitals, shopping malls, office buildings, and fire stations. The electricity consumption of each location within the current collection period is obtained, and the locations are arranged in descending order of electricity consumption to obtain a power supply sequence. Then, the wind power is allocated according to the electricity consumption of each location, with locations with higher electricity consumption receiving more power.

[0070] Step S104: If the difference is not less than the preset first auxiliary power supply threshold, then obtain the power consumption of the previous collection cycle of the current power supply area.

[0071] Step S105: Calculate the difference in power consumption between the current data collection cycle and the previous data collection cycle.

[0072] Step S106: Determine whether the difference in power consumption is not less than the preset second auxiliary power supply threshold.

[0073] In this embodiment, the preset second auxiliary power supply threshold is the maximum value for determining whether the power consumption has suddenly increased sharply. The difference in power consumption is the power consumption of the current collection cycle minus the power consumption of the previous collection cycle. The larger the difference in power consumption, the more the power consumption has increased, indicating that the power consumption of the current collection cycle has surged compared with the previous collection cycle, and there is a possibility that the power supply network cannot supply power normally. The preset second auxiliary power supply threshold needs to be set according to actual needs, and no specific limitation is made here.

[0074] Step S107: If the difference in power consumption is not less than the second auxiliary power supply threshold, then the power generated by the wind power generation will be connected to the power supply network for auxiliary power supply.

[0075] Step S108: If the difference in power consumption is less than the second auxiliary power supply threshold, then store the power generated by wind power generation.

[0076] After step S108, the power supply status of the current power supply area is obtained, including normal power supply and no power supply; when the power supply status is no power supply, all power-consuming places in the current power supply area and the corresponding power consumption type of the power-consuming places are obtained; the power allocation rules are obtained, and the power supply of wind power generation to the power-consuming places is based on the power allocation rules and power consumption type; when the power supply status is normal power supply, the power generated by wind power generation continues to be stored.

[0077] Specifically, the power consumption sites are classified according to the preset first-level classification rules to generate the first power supply level; the power consumption types are classified according to the preset second-level classification rules to generate the second power supply level; the historical power consumption of the power consumption type is obtained, and the power supply for the wind power generation of the power consumption sites is based on the first power supply level, the second power supply level, and the historical power consumption of the power consumption type.

[0078] In this embodiment, when the power supply status is normal, it means that the power supply of the power supply network can meet the power demand of the current power supply area. When the power supply status is no power supply, it means that the power supply network is abnormal and can no longer supply power to the current power supply area, and the current power supply area is in a state of no power available.

[0079] When the power supply status is no power supply, the power-using places in the current power supply area will be classified according to the first-level classification rule. The first-level classification rule is to arrange the power-using places according to their importance to people's livelihood. For example, the importance of fire stations and hospitals is higher than that of residential areas and office buildings. However, the specific determination of the importance of power-using places in the first-level classification rule needs to be set by the actual needs of the current power supply area. No specific limit is made here.

[0080] The second-level classification rule is to rank the importance of different types of electricity in different locations. For example, the importance of electricity for surgery in a hospital is higher than the importance of electricity for outpatient drug dispensing in a hospital. However, the specific determination of the importance of different types of electricity in the second-level classification rule needs to be set according to the actual needs of the current location and is not specifically limited here.

[0081] The identified power-consuming locations and types are then sorted according to the classification results. Historical electricity consumption for each power type within each location is obtained. Wind power is prioritized for allocation to the top-ranked locations and types based on historical consumption, thus minimizing the impact on people's livelihoods. It should be noted that the sorting method can be a direct combination of descending order of importance based on the location and descending order of importance based on the type of power consumption, such as hospital operating rooms, hospital pharmacies, fire station water pumps, and fire station canteens. Alternatively, it can be a combination of descending order of importance based on both location and type of power consumption, followed by a further ranking based on overall importance, such as hospital operating rooms, fire station water pumps, hospital pharmacies, and fire station canteens. No specific limitations are imposed here.

[0082] In this embodiment, the current power storage capacity of the power storage system and the maximum power storage capacity of the power storage system are obtained, and the difference between the current power storage capacity and the maximum storage capacity is calculated. It is determined whether the difference in storage capacity is not less than a preset storage threshold. If the difference in storage capacity is less than the preset storage threshold, a backup power storage system is obtained, and the power generated by wind power generation is stored in the backup power storage system. If the difference in storage capacity is not less than the preset storage threshold, the power generated by wind power generation is stored in the current power storage system.

[0083] The maximum power storage capacity of the power storage system is its limit. Exceeding this limit results in wasted wind power. To minimize this waste, power must be stored in a backup power storage system before reaching the maximum capacity. The difference between the current and maximum power storage capacity is calculated. This difference is then compared to a preset storage threshold. If the difference is less than the threshold, the current capacity is close to the maximum, posing a risk of wasted power. In this case, the wind power should be stored in the backup system. If the difference is greater than or equal to the threshold, the current capacity is within a safe range, and the system can continue to operate. The preset storage threshold is the maximum value required for the current power storage system to continue supplying power. This threshold is set based on actual needs and is not specifically defined here.

[0084] In this embodiment, historical electricity consumption information and power supply strategies for the current power supply area are obtained, and electricity generated by wind power generation in the current power supply area is supplied based on the historical electricity consumption information and power supply strategies.

[0085] Specifically, the system obtains the power supply load value and historical maximum power consumption value of the power supply network; determines whether the historical maximum power consumption value is not less than the power supply load value; if the historical maximum power consumption value is not less than the power supply load value, it obtains the time period corresponding to the historical maximum power consumption value; and connects the wind power generation to the power supply network in advance for auxiliary power supply before each time period arrives.

[0086] In this embodiment, electricity consumption at certain times of day, certain days of month, or certain months of year will be significantly higher than the average electricity consumption. This situation, where electricity consumption exceeds the average, is referred to as a peak electricity consumption period. The historical maximum electricity consumption value (i.e., the peak electricity consumption period value) is compared with the power supply network's load threshold. When the historical maximum electricity consumption value is greater than or equal to the power supply load threshold, the peak electricity consumption period is predicted in advance. Before the next peak electricity consumption period arrives, wind power is connected to the power supply network in advance, thereby reducing the possibility of reaching the power supply load value and causing power supply anomalies. When connecting wind power to the power supply network, due to the instability of wind power generation, the power supply strategy can be to use only the power from the energy storage system for auxiliary power supply upon connection, or to use the power from the wind power generation system simultaneously with the energy storage system for auxiliary power supply.

[0087] Figure 2This is a structural block diagram of a smart power distribution device 200 based on wind power generation, provided for an embodiment of the application.

[0088] like Figure 2 As shown, the intelligent power distribution device 200 based on wind power generation mainly includes:

[0089] The regional electricity consumption acquisition module 201 is used to acquire the current collection period and the current power supply area's current collection period electricity consumption and the power supply threshold of the power supply network, and to calculate the difference between the current collection period electricity consumption and the power supply threshold.

[0090] The power supply difference judgment module 202 is used to determine whether the difference between power supply and consumption is not less than a preset first auxiliary power supply threshold.

[0091] The first auxiliary power supply module 203 is used to connect the power generated by wind power generation to the power supply network for auxiliary power supply;

[0092] The previous power consumption acquisition module 204 is used to acquire the power consumption of the current power supply area in the previous acquisition cycle;

[0093] The electricity consumption difference calculation module 205 is used to calculate the difference between the electricity consumption in the current collection cycle and the electricity consumption in the previous collection cycle.

[0094] The power consumption difference judgment module 206 is used to determine whether the difference in power consumption is not less than the preset second auxiliary power supply threshold.

[0095] The second auxiliary power supply module 207 is used to connect the power generated by wind power generation to the power supply network for auxiliary power supply;

[0096] Wind power generation storage module 208 is used to store electricity generated by wind power generation.

[0097] As an optional implementation of this embodiment, the first auxiliary power supply module 203 is specifically used to obtain all the power-consuming places in the current power supply area and the power consumption of each power-consuming place; arrange the power consumption of the places in descending order of the value to generate a power supply sequence; obtain the power supply rules, and provide auxiliary power supply to the power-consuming places based on the power supply rules and the power supply sequence.

[0098] As an optional implementation of this embodiment, the wind power-based intelligent power distribution device 200 further includes:

[0099] The status acquisition module is used to acquire the power supply status of the current power supply area, which includes normal power supply and no power supply.

[0100] The location acquisition module is used to acquire all power-consuming locations and their corresponding power consumption types in the current power supply area when the power supply status is no power supply.

[0101] The site power supply module is used to obtain power allocation rules and supply power to the site using wind power generation based on the power allocation rules and power type.

[0102] The power storage module is used to continue storing the electricity generated by wind power when the power supply is normal.

[0103] In this optional embodiment, the site power supply module is specifically used to classify the power consumption site according to a preset first level classification rule to generate a first power supply level; classify the power consumption type according to a preset second level classification rule to generate a second power supply level; obtain the historical power consumption of the power consumption type; and supply power to the power consumption site using wind power generation based on the first power supply level, the second power supply level, and the historical power consumption of the power consumption type.

[0104] In this optional embodiment, the power storage module is specifically used to obtain the current power storage capacity of the power storage system and the maximum power storage capacity of the power storage system, calculate the difference between the current power storage capacity and the maximum storage capacity; determine whether the difference in storage capacity is not less than a preset storage threshold; if the difference in storage capacity is less than the preset storage threshold, then obtain a backup power storage system and store the wind power generated in the backup power storage system; if the difference in storage capacity is not less than the preset storage threshold, then store the wind power generated in the current energy storage system.

[0105] As an optional implementation of this embodiment, the wind power-based intelligent power distribution device 200 further includes:

[0106] The strategy power supply module is used to obtain historical electricity consumption information and power supply strategies for the current power supply area, and to supply electricity to the wind power generation area based on the historical electricity consumption information and power supply strategies.

[0107] In this optional embodiment, the strategy power supply module is specifically used to obtain the power supply load value and the historical maximum power consumption value of the power supply network; determine whether the historical maximum power consumption value is not less than the power supply load value; if the historical maximum power consumption value is not less than the power supply load value, then obtain the time period corresponding to the historical maximum power consumption value; before each time period arrives, connect the wind power generation to the power supply network in advance for auxiliary power supply.

[0108] In one example, the module in any of the above devices may be one or more integrated circuits configured to implement the above methods, such as one or more application-specific integrated circuits (ASICs), or one or more digital signal processors (DSPs), or one or more field-programmable gate arrays (FPGAs), or a combination of at least two of these integrated circuit forms.

[0109] For example, when modules in a device can be implemented via a processing element scheduler, the processing element can be a general-purpose processor, such as a central processing unit (CPU) or other processor capable of calling programs. Alternatively, these modules can be integrated together as a system-on-a-chip (SOC).

[0110] Those skilled in the art will clearly understand that, for the sake of convenience and brevity, the specific working process of the above-described device and module can be referred to the corresponding process in the foregoing method embodiments, and will not be repeated here.

[0111] Figure 3 This is a structural block diagram of the electronic device 300 provided in an embodiment of this application.

[0112] like Figure 3 As shown, the electronic device 300 includes a processor 301 and a memory 302, and may further include one or more of an information input / output (I / O) interface 303, a communication component 304, and a communication bus 305.

[0113] The processor 301 controls the overall operation of the electronic device 300 to complete all or part of the steps of the aforementioned wind power-based smart power distribution method. The memory 302 stores various types of data to support the operation of the electronic device 300. This data may include, for example, instructions for any application or method operating on the electronic device 300, as well as application-related data. The memory 302 can be implemented by any type of volatile or non-volatile storage device or a combination thereof, such as one or more of Static Random Access Memory (SRAM), Electrically Erasable Programmable Read-Only Memory (EEPROM), Erasable Programmable Read-Only Memory (EPROM), Programmable Read-Only Memory (PROM), Read-Only Memory (ROM), magnetic storage, flash memory, magnetic disk, or optical disk.

[0114] I / O interface 303 provides an interface between processor 301 and other interface modules, such as keyboards, mice, and buttons. These buttons can be virtual or physical. Communication component 304 is used for wired or wireless communication between electronic device 300 and other devices. Wireless communication includes Wi-Fi, Bluetooth, Near Field Communication (NFC), 2G, 3G, or 4G, or a combination thereof. Therefore, the corresponding communication component 304 may include a Wi-Fi component, a Bluetooth component, and an NFC component.

[0115] The electronic device 300 may be implemented by one or more application-specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), field-programmable gate arrays (FPGAs), controllers, microcontrollers, microprocessors, or other electronic components to execute the wind power-based smart power distribution method given in the above embodiments.

[0116] The communication bus 305 may include a path for transmitting information between the aforementioned components. The communication bus 305 may be a PCI (Peripheral Component Interconnect) bus or an EISA (Extended Industry Standard Architecture) bus, etc. The communication bus 305 may be divided into an address bus, a data bus, a control bus, etc.

[0117] Electronic device 300 may include, but is not limited to, mobile terminals such as mobile phones, laptops, digital radio receivers, PDAs (personal digital assistants), PADs (tablet computers), PMPs (portable multimedia players), and in-vehicle terminals (such as in-vehicle navigation terminals), as well as fixed terminals such as digital TVs and desktop computers, and may also be servers.

[0118] This application also provides a computer-readable storage medium storing a computer program, which, when executed by a processor, implements the steps of the above-described intelligent power distribution method based on wind power generation.

[0119] The computer-readable storage medium may include various media capable of storing program code, such as USB flash drives, portable hard drives, read-only memory (ROM), random access memory (RAM), magnetic disks, or optical disks.

[0120] The terms “comprising,” “including,” or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, method, article, or apparatus.

[0121] The above description is merely a preferred embodiment of this application and an explanation of the technical principles employed. Those skilled in the art should understand that the scope of this application is not limited to technical solutions formed by specific combinations of the above-described technical features, but should also cover other technical solutions formed by arbitrary combinations of the above-described technical features or their equivalents without departing from the foregoing application concept. For example, technical solutions formed by substituting the above features with (but not limited to) technical features with similar functions claimed in this application.

Claims

1. A smart power distribution method based on wind power generation, characterized in that, include: The current data collection period and the current power supply area are obtained, along with the current data collection period's electricity consumption and the power supply threshold of the power supply network. The difference between the current data collection period's electricity consumption and the power supply threshold is calculated. The power supply network's electricity comes from thermal power generation and wind power generation, with thermal power generation being the main power source. The power supply threshold is the maximum amount of power that thermal power generation can provide. Determine whether the difference between the power supply and consumption is not less than a preset first auxiliary power supply threshold; If the difference between the power supply and consumption is less than the preset first auxiliary power supply threshold, then the power generated by the wind power generation will be connected to the power supply network for auxiliary power supply. If the difference between power supply and consumption is not less than the preset first auxiliary power supply threshold, then the power consumption of the current power supply area in the previous collection cycle is obtained; Calculate the difference in electricity consumption between the current data collection cycle and the previous data collection cycle; Determine whether the difference in power consumption is not less than a preset second auxiliary power supply threshold; If the difference in power consumption is not less than the second auxiliary power supply threshold, then the power generated by the wind power generation will be connected to the power supply network for auxiliary power supply. If the difference in power consumption is less than the second auxiliary power supply threshold, then the power generated by the wind power generation is stored; After storing the electricity generated by the wind power, the method further includes: Obtain the power supply status of the current power supply area, including normal power supply and no power supply; When the power supply status is no power supply, obtain all power-consuming locations in the current power supply area and the power consumption type corresponding to each power-consuming location; Obtain the power allocation rules, and supply the wind power generated at the power consumption site based on the power allocation rules and the power consumption type; When the power supply status is normal, the power generated by the wind power generation continues to be stored; The process of supplying electricity to the power-consuming location using the wind power generation based on the power allocation rules and the power consumption type includes: The power consumption sites are classified into levels according to a preset first-level classification rule to generate a first power supply level; The electricity consumption type is classified into levels according to a preset second-level classification rule to generate a second power supply level; The historical electricity consumption of the electricity consumption type is obtained, and the electricity used by the wind power generation is supplied to the electricity consumption site based on the first power supply level, the second power supply level and the historical electricity consumption of the electricity consumption type.

2. The method according to claim 1, characterized in that, The process of connecting wind power generation to the power supply network for auxiliary power supply includes: Obtain all electricity-consuming locations in the current power supply area and the electricity consumption of each location; Arrange the power consumption of the locations in descending order of their numerical values ​​to generate a power supply sequence; Obtain power supply rules, and provide auxiliary power supply to the power consumption sites based on the power supply rules and the power supply sequence; wherein, the power supply rules are: allocate wind power according to the power consumption of each power consumption site, and the power consumption site with the larger power consumption receives more power.

3. The method according to claim 1, characterized in that, The continued storage of the wind-generated electricity includes: Obtain the current power storage capacity of the power storage system and the maximum power storage capacity of the power storage system, and calculate the difference between the current power storage capacity and the maximum power storage capacity; Determine whether the difference in storage quantity is not less than a preset storage threshold; If the difference in storage volume is less than the preset storage threshold, then a backup power storage system is obtained, and the power generated by the wind power generation is stored in the backup power storage system. If the difference in storage volume is not less than the preset storage threshold, then the electricity generated by the wind power generation will be stored in the current power storage system.

4. The method according to claim 1, characterized in that, After storing the electricity generated by the wind power, the method further includes: Obtain historical electricity consumption information and power supply strategy for the current power supply area, and supply electricity to the current power supply area using the wind power generation based on the historical electricity consumption information and the power supply strategy.

5. The method according to claim 4, characterized in that, The process of supplying electricity to the current power supply area using the wind power generated based on the historical electricity consumption information and the power supply strategy includes: Obtain the power supply load value and historical maximum power consumption value of the power supply network; Determine whether the historical maximum electricity consumption is not less than the power supply load value; If the historical maximum electricity consumption is not less than the power supply load value, then obtain the time period corresponding to the historical maximum electricity consumption; Before each of the specified time periods, the power generated by the wind power generation is connected to the power supply network in advance for auxiliary power supply.

6. A smart power distribution device based on wind power generation, characterized in that, include: The regional electricity consumption acquisition module is used to acquire the current collection period and the current power supply area's current collection period electricity consumption and the power supply threshold of the power supply network, and calculate the difference between the current collection period electricity consumption and the power supply threshold. The power supply network's electricity comes from thermal power generation and wind power generation, with thermal power generation being the main power source, and the power supply threshold being the maximum power supply that thermal power generation can provide. The power supply difference judgment module is used to determine whether the difference between the power supply and consumption is not less than a preset first auxiliary power supply threshold. The first auxiliary power supply module is used to connect the power generated by wind power generation to the power supply network for auxiliary power supply when the power supply difference judgment module determines that the difference between power supply and consumption is less than the preset first auxiliary power supply threshold. The previous power consumption acquisition module is used to acquire the power consumption of the current power supply area in the previous collection cycle when the power supply difference judgment module determines that the difference between power supply and consumption is not less than the preset first auxiliary power supply threshold. The electricity consumption difference calculation module is used to calculate the difference between the electricity consumption in the current collection cycle and the electricity consumption in the previous collection cycle. The power consumption difference judgment module is used to determine whether the difference in power consumption is not less than a preset second auxiliary power supply threshold. The second auxiliary power supply module is used to connect the wind power generation to the power supply network for auxiliary power supply when the power consumption difference judgment module determines that the difference in power consumption is not less than the second auxiliary power supply threshold. A wind power generation storage module is used to store the power generated by the wind power generation when the power consumption difference judgment module determines that the difference in power consumption is less than the second auxiliary power supply threshold. The status acquisition module is used to acquire the power supply status of the current power supply area, which includes normal power supply and no power supply. The location acquisition module is used to acquire all power-consuming locations in the current power supply area and the corresponding power consumption type of the power-consuming locations when the power supply status is no power supply. The site power supply module is used to acquire power allocation rules and supply power to the site using the wind power generation based on the power allocation rules and the power consumption type. A power storage module is used to continue storing the power generated by the wind power generation when the power supply status is normal. The power supply module for the location is specifically used to: classify the power consumption location according to a preset first-level classification rule, and generate a first power supply level; The electricity consumption type is classified into levels according to a preset second-level classification rule to generate a second power supply level; The historical electricity consumption of the electricity consumption type is obtained, and the electricity used by the wind power generation is supplied to the electricity consumption site based on the first power supply level, the second power supply level and the historical electricity consumption of the electricity consumption type.

7. An electronic device, characterized in that, Includes a processor, which is coupled to a memory; The processor is configured to execute a computer program stored in the memory, causing the electronic device to perform the method as described in any one of claims 1 to 5.

8. A computer-readable storage medium, characterized in that, It includes a computer program or instructions that, when run on a computer, cause the computer to perform the method as described in any one of claims 1 to 5.