CN117576348A - A new power system display platform and method based on the Metaverse - Google Patents

Abstract

The utility model relates to the field of power systems, and discloses a novel power system display platform and method based on metauniverse. The present invention integrates meta-space technology with power system management, which enables users to enter a virtual power system world, actual experience and operating system, which is not possible in conventional SCADA or EMS systems, and users to enter a virtual power system world, which perfectly simulates aspects of an actual power system, including power stations, transmission lines, substations and end users, which enables users to actually experience and operate the power system in the virtual environment, thereby better understanding and managing it.

Description

A new power system display platform and method based on the Metaverse

Technical field

The present invention relates to the technical field of power systems, specifically a new power system display platform and method based on the metaverse.

Background technique

Over the past few decades, power system management has relied on traditional monitoring and management methods, including SCADA systems, EMS systems, simulators and training facilities, and market trading platforms. Although these methods help maintain the stability and efficiency of the power system to a certain extent, they also have some limitations.

Traditional SCADA systems provide real-time data monitoring, but usually lack comprehensiveness and interactivity and cannot truly simulate the operation of the power system. EMS systems mainly focus on the operation and planning of power systems, but do not provide virtual training and simulation functions. Although simulators and training facilities are used to train operation and maintenance personnel, they are often separated from actual operations and difficult to provide a real virtual experience. The market trading platform is mainly used for market transactions and clearing, rather than the operation and management of the power system.

These traditional methods perform well in some aspects, but lack integration, comprehensiveness, and practical simulation. In view of the problems existing in the existing technology, the present invention provides a new power system display platform and method based on the metaverse to solve the shortcomings of the existing technology.

Contents of the invention

In view of the shortcomings of the existing technology, the present invention provides a new power system display platform and method based on the Metaverse. By integrating Metaverse technology into power system management, an innovative and highly integrated platform is provided to improve the power system. visualization, training and decision support, thereby improving the efficiency and reliability of power systems.

In order to achieve the above objectives, the present invention is realized through the following technical solutions: a new power system display platform based on the metaverse, including

Virtual power system environment, a virtual environment used to simulate the power system;

The power system environment includes a three-dimensional modeling and scene generation module, a virtual map and geographical information system module, a user interface and interaction module, a physics engine module, a ray tracing and rendering module, a virtual equipment and energy generation module, virtual sensors and data collection module, virtual market and economic system module, virtual fault module and emergency response module, data export and report generation module;

The power system topology module is used to display the topology of the power system;

Real-time monitoring and data visualization module for providing real-time data and presenting data in a visual way;

Power equipment management module, used to manage power equipment and monitor its status and performance;

Load management and forecasting module for load optimization and distribution;

The load management and prediction module consists of a historical load data collection module, a real-time load data collection module, a load prediction algorithm, a load prediction model, a load analysis tool module, a load balancing strategy module, a load adjustment and control module, a load management report module and an instrument It consists of disk, user demand forecast and load forecast error analysis modules;

Energy market module, used to display energy market prices and related data;

Fault simulation and crisis management module for simulating power system fault and crisis situations;

The fault simulation and crisis management module consists of a fault situation setting module, a fixed simulation module, a real-time monitoring and response module, an emergency response plan module, a simulated event recording module, a crisis management tool module, a simulation result analysis module, a drill and training module, Composed of communication and collaboration tool modules, security and permission control modules;

Decision support tools to assist users in making decisions;

The decision support tools include data collection and integration units, data analysis tools, decision support systems, multi-criteria decision analysis units, decision tree and scenario analysis units, risk assessment and management units, decision audit and tracking units, collaboration and team decision support unit;

Social interaction and collaboration module to support multi-user interaction and collaboration;

Virtual training and simulation modules for training power system operation and maintenance personnel.

Preferably, a new power system display method based on the metaverse is characterized by including the following steps:

S1. Enter the virtual power system environment:

Users enter the virtual power system environment through head-mounted VR devices;

S2. View real-time data and visual presentation of the power system:

Users can view real-time data of the power system through the interface in the virtual environment, including but not limited to grid load, frequency and voltage, as well as visual graphics to present these data;

S3. Simulate different scenarios and decisions of the power system:

Users can use tools in the virtual environment to simulate different scenarios;

S4. Collaborate and interact socially with other users:

Multiple users can interact and collaborate in the same virtual power system environment to solve problems and make decisions together;

S5. Train power system operation and maintenance personnel to simulate various situations:

Users can use the virtual environment to train power system operation and maintenance personnel, allowing them to simulate a variety of situations, including but not limited to responding to faults, emergencies, and maintenance operations.

Preferably, the power system topology module consists of a geographical information system integration module, a power equipment element library module, a virtual map and terrain module, a topology editing tool module, an automatic topology generation module, a label and information display module, and a power flow direction and load distribution module. It consists of modules, hierarchical structure and filtering modules, navigation and interactive tool modules, and virtual topology analysis modules.

Preferably, the real-time monitoring and data visualization module consists of a data collection and transmission unit, a data storage and management unit, a real-time monitoring interface unit, a data analysis and alarm unit, a data visualization tool unit, a custom dashboard and chart unit, and historical data. It is composed of query and review unit, real-time map view unit, multi-screen support unit, real-time notification and communication unit, and data export and sharing unit.

Preferably, the power equipment management module consists of equipment ledger and database, equipment status monitoring unit, equipment control and operation unit, equipment performance analysis unit, equipment maintenance plan and calendar unit, backup equipment management unit, equipment health monitoring unit, equipment It is composed of reporting and logging unit, remote monitoring and operation unit, security and authority control unit.

Preferably, the energy market module consists of market design and rules, market participants, market trading platform, electricity price formation, supply and demand simulation, market analysis tools, market simulation parameter settings, market result reporting and analysis, and market transaction history storage.

Preferably, the social interaction and collaboration module consists of a user management and permission control unit, a user profile and social network unit, a real-time chat and instant messaging unit, a knowledge base and document management unit, a notification and reminder unit, and a user evaluation and feedback unit. , virtual conference and video conferencing unit, user analysis and statistics unit.

Preferably, the virtual training and simulation module consists of course management and course creation, virtual training environment, multimedia content, interactive tests and tests, virtual laboratory, simulation console and tools, performance evaluation and feedback, progress tracking and reporting, virtual Components of scenarios and cases, social interaction and collaboration, virtual mentors and support, user analytics and statistics.

The invention provides a new power system display platform and method based on the metaverse. It has the following beneficial effects:

1. This invention integrates Metaverse technology with power system management, which enables users to enter a virtual power system world, actual experience and operating systems. This is impossible in traditional SCADA or EMS systems. Users can enter a virtual power system world. Within the power system world, this virtual environment perfectly simulates all aspects of the actual power system, including power stations, transmission lines, substations and end users. This allows users to actually experience and operate the power system in the virtual environment, thereby better understanding Understand and manage it.

2. The new power system display platform based on the Yuanverse provided by the present invention integrates multiple core modules, including load management, market transactions, crisis management, decision support and training. These modules work closely together so that users can execute on one platform Various tasks without the need to switch to different applications or systems, this integration provides greater efficiency and user-friendliness, significantly improving efficiency compared to the fragmented nature of traditional systems.

3. The new power system display platform based on the Metaverse provided by the present invention far exceeds the real-time performance of traditional systems. It can respond to changes in the power system almost immediately, and at the same time provides a high degree of interactivity. Users can simulate operating the power system, adjust parameters, and predict results and observe real-time effects, which is critical for training and decision-making.

4. The new power system display platform based on the Metaverse provided by the present invention provides a virtual laboratory and simulation environment for training power system operation and maintenance personnel and simulating various scenarios, from daily operations to emergencies. This practical The simulation nature helps increase the skill level of operations personnel and make them better prepared to respond to crises, while also enabling users to participate in training together, share information and make team decisions in a virtual environment, which is often lacking in traditional systems. Social interactivity, and this system provides rich decision support tools to help power system managers make informed decisions, whether in market transactions, load management, crisis response or system optimization, which traditional systems usually lack Function.

Description of the drawings

Figure 1 is a system expansion diagram of the new power system display platform based on the Metaverse;

Figure 2 is the system framework diagram of the new power system display platform based on the Metaverse;

Figure 3 shows the virtual power system environment framework diagram of the new power system display platform based on the Metaverse;

Figure 4 is a frame diagram of the power system detox module of the new power system display platform based on the Metaverse;

Figure 5 is a frame diagram of the real-time monitoring and data visualization module of the new power system display platform based on the Yuanverse;

Figure 6 is a framework diagram of the power equipment management module of the new power system display platform based on the Yuanverse;

Figure 7 is a frame diagram of the load management and forecast module of the new power system display platform based on the Metaverse;

Figure 8 is the energy market module framework diagram of the new power system display platform based on the Yuanverse;

Figure 9 is a framework diagram of the fault simulation and crisis management module of the new power system display platform based on the Metaverse;

Figure 10 is a framework diagram of the decision support tool of the new power system display platform based on the Metaverse;

Figure 11 is a framework diagram of the social mutual assistance and collaboration module of the new power system display platform based on the Metaverse;

Figure 12 is a framework diagram of the virtual training and simulation module of the new power system display platform based on the Metaverse.

Detailed ways

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings of the description of the present invention. Obviously, the described embodiments are only some of the embodiments of the present invention, rather than all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art without creative efforts fall within the scope of protection of the present invention.

Example:

Referring to Figures 1 to 12, embodiments of the present invention provide a new power system display platform based on the Metaverse, including:

Virtual power system environment, a virtual environment used to simulate the power system;

The power system environment includes three-dimensional modeling and scene generation modules, virtual maps and geographic information system modules, user interface and interaction modules, physics engine modules, ray tracing and rendering modules, virtual equipment and energy generation modules, virtual sensors and data collection, virtual Market and economic system module, virtual fault module and emergency response module, data export and report generation module;

The three-dimensional modeling and scene generation module is used to create a three-dimensional environment of the virtual power system, including but not limited to cities, terrains, buildings and power equipment; the virtual map and geographical information system modules are used to build virtual maps to display the geographical layout of the power system and topology; the user interface and interaction module provides ways for users to interact with the virtual environment, including but not limited to head-mounted VR devices, gesture controls, controllers, keyboards, mice, and voice commands for users to browse, Select devices and perform operations; the physics engine module is used to simulate the physical properties of objects in the virtual environment, including gravity, collision, dynamics, and fluid dynamics; the ray tracing and rendering module is used to simulate light propagation, including lighting, shadows, and reflections; The virtual equipment and energy generation module is used to simulate various equipment of the power system, including but not limited to generators, transformers and transmission lines, and simulate their energy generation and transmission; while monitoring the operating parameters and efficiency of the equipment; virtual sensors and data The acquisition module is used to simulate various sensors and collect real-time data of the power system, including but not limited to voltage, current and temperature; these data are used for real-time monitoring and analysis; the virtual market and economic system module is used to simulate the operation and price of the power market mechanism and user transactions; the virtual fault module and emergency response module are used to simulate various fault conditions, including but not limited to equipment failure, power outage and natural disasters; the data export and report generation module is used for users to export data of the virtual power system environment;

These modules work together to create a comprehensive virtual power system environment where users can interact, explore, simulate and monitor all aspects of the power system.

This invention combines metaverse technology with power system management, allowing users to enter a virtual power system world through the use of VR equipment. This virtual environment perfectly simulates all aspects of the actual power system, including power stations, transmission lines, substations and terminals. This enables users to actually feel and operate the power system in a virtual environment to better understand and manage it.

The power system topology module is used to display the topology of the power system;

Real-time monitoring and data visualization module for providing real-time data and presenting data in a visual way;

Power equipment management module, used to manage power equipment and monitor its status and performance;

Load management and forecasting module for load optimization and distribution;

The load management and prediction module consists of a historical load data collection module, a real-time load data collection module, a load prediction algorithm, a load prediction model, a load analysis tool module, a load balancing strategy module, a load adjustment and control module, a load management report module and a dashboard, It consists of user demand forecasting and load forecasting error analysis modules;

The historical load data collection module is used to collect and store historical load data, including electricity consumption by hour, day, week or month. These data can be used for prediction and analysis; the real-time load data collection module is used to collect and monitor the real-time load of the power system. Data to help manage and adjust power distribution in real time; load prediction algorithms include various load prediction algorithms, such as time series analysis, neural network, regression analysis, etc., used to predict future load demand; load prediction models are used to build and manage loads Forecasting models that can make personalized forecasts for different time scales (hours, days, seasons, etc.) and regions; load analysis tool modules that provide tools to analyze historical load data and identify trends, seasonality, periodicity, and special events to help Improve the accuracy of load forecasting; the load balancing strategy module is used to formulate load balancing strategies to ensure that the power system can meet demand during peak hours or emergencies; the load adjustment and control module allows the load of the power system to be adjusted based on actual conditions Adjustment and control to ensure the stability of power supply; load management reporting module and dashboard provide tools to generate load management reports and dashboards to visually display load data, forecast results and execution strategies; user demand forecasting, allowing forecasting of different users The power demand of the group to assist in formulating the load management strategy of distributed energy; the load prediction error analysis module is used to analyze the error between the load prediction and the actual load to improve the accuracy of the load prediction model;

These sub-modules work together to enable power system managers to better understand and predict power load demands to effectively manage power supply and reduce overloading or waste;

Energy market module, used to display energy market prices and related data;

Fault simulation and crisis management module for simulating power system fault and crisis situations;

The fault simulation and crisis management module consists of a fault situation setting module, a fixed simulation module, a real-time monitoring and response module, an emergency response plan module, a simulated event recording module, a crisis management tool module, a simulation result analysis module, a drill and training module, a communication and It consists of collaboration tool module, security and permission control module, as follows:

Fault condition setting module: This sub-module allows users to set different types of fault conditions, such as equipment failure, line failure, severe weather, natural disasters, etc. Users can specify the type, location and duration of the fault;

Fault Simulation Module: Tool for simulating various fault conditions, including equipment failure, power outage, voltage drop, overload, etc., which can lead to abnormal conditions in the power system;

Real-time monitoring and response module: allows users to monitor the performance of the power system in real-time during fault simulation. This unit can display real-time data, alarms and status changes;

Emergency response plan module: This sub-module is used to develop and manage emergency response plans, including startup of backup equipment, load distribution, communication strategies and recovery procedures;

Simulated event recording module: stores and records simulated fault event data for subsequent analysis and reporting, including the time, cause and recovery time of the event;

Crisis Management Tools Module: Provides tools to manage crisis situations, including crisis response, team communications, resource allocation, and emergency notifications;

Simulation result analysis module: used to analyze the results of simulated fault conditions and crisis events, including the stability, recoverability and economic impact of the power system;

Drill and training modules: Provide training scenarios that simulate faults and crisis events to help power system operation and maintenance personnel become familiar with emergency response procedures;

Communication and collaboration tools module: allows teams to work and communicate together to effectively respond to breakdowns and crisis situations, this can include instant messaging, collaboration platforms and call recording;

Security and access control module: used to ensure that only authorized users can access fault simulation and crisis management tools to maintain the security of the power system;

The collaborative work of these sub-modules enables power system managers and operation and maintenance personnel to simulate various fault situations and crisis events, formulate corresponding management strategies, and prepare in advance to deal with possible problems.

Provide virtual laboratories and simulation environments for training power system operation and maintenance personnel and simulating various scenarios, from daily operations to emergencies. This practical simulation nature helps improve the skill level of operation and maintenance personnel and make them more Be well prepared to respond to crises.

Decision support tools to assist users in making decisions;

Decision support tools include data collection and integration units, data analysis tools, decision support systems, multi-criteria decision analysis units, decision tree and scenario analysis units, risk assessment and management units, decision auditing and tracking units, collaboration and team decision support units, details as follows:

Data collection and integration unit: This unit is responsible for collecting data from multiple data sources, including real-time monitoring data, historical data, market data, weather data, etc., and it integrates these data for further analysis;

Data analysis tools: Provides a variety of analysis tools, including statistical analysis, trend analysis, predictive analysis, machine learning and data mining tools. This helps understand data and discover patterns;

Modeling and Simulation Unit: This unit includes building and running models to simulate different aspects of the power system, such as power supply, demand, price, risk, etc. Simulation can be used to test the effects of different decisions;

Risk assessment and management unit: used to assess and manage risks related to different decisions, including market risk, operational risk, policy risk, etc.;

Decision audit and tracking unit: Provides audit functions to record the process and rationale for decision-making, which helps ensure the transparency and compliance of decisions;

Collaboration and team decision support unit: allows multiple decision makers to work together and share data and analysis results to reach consensus and make decisions.

Together, these units form a decision support tool that helps power system managers and decision-makers make informed strategic and operational decisions to improve power system efficiency and reliability, whether in market trading, load management, crisis response, or system Optimization aspects;

Social interaction and collaboration module to support multi-user interaction and collaboration, promote interaction and collaboration between users, users can participate in training together, share information, and even make team decisions in a virtual environment, which helps knowledge transfer and teamwork ;

Virtual training and simulation modules for training power system operation and maintenance personnel.

This system integrates multiple core modules, including load management, market transactions, crisis management, decision support and training. These modules work closely together to allow users to perform various tasks on one platform without switching to different applications or systems. , this integration provides greater efficiency and user-friendliness.

A new power system display method based on the metaverse, including the following steps:

S1. Enter the virtual power system environment:

Users enter the virtual power system environment through head-mounted VR devices;

S2. View real-time data and visual presentation of the power system:

Users can view real-time data of the power system through the interface in the virtual environment, including but not limited to grid load, frequency and voltage, as well as visual graphics to present these data;

S3. Simulate different scenarios and decisions of the power system:

Users can use tools in the virtual environment to simulate different scenarios;

S4. Collaborate and interact socially with other users:

Multiple users can interact and collaborate in the same virtual power system environment to solve problems and make decisions together;

S5. Train power system operation and maintenance personnel to simulate various situations:

Users can use the virtual environment to train power system operation and maintenance personnel, allowing them to simulate a variety of situations, including but not limited to responding to faults, emergencies, and maintenance operations.

The power system topology module consists of a geographic information system integration module, a power equipment element library module, a virtual map and terrain module, a topology editing tool module, an automatic topology generation module, a label and information display module, a power flow and load distribution module, a hierarchical structure and It is composed of filtering module, navigation and interactive tool module, and virtual topology analysis module.

The geographic information system integration module is used to integrate the geographic information of the power system with virtual maps and topological maps. It can display the precise geographical location of power equipment, such as substations, transmission lines, transformers, etc.; the power equipment element library module includes elements and models of various power equipment, such as generators, transformers, circuit breakers, switches and electrical lines. These primitives can be used to build virtual topology of the power system; the virtual map and terrain modules are used to create virtual geographical environments, including cities, mountains, lakes, etc., which help users understand the geographical distribution of the power system; the topology editing tool module allows users to Manually edit the power system topology. Users can add, delete or connect devices to simulate different configurations of the power system; the automatic topology generation module can automatically generate a topology diagram of the power system based on the input power equipment data. It can identify the connection relationships between devices and create corresponding graphics; the label and information display module is used to add labels and information boxes to display detailed information of each power device, such as device name, rated capacity, status and parameters; Electricity The flow direction and load distribution module illustrates the flow direction and load distribution of power through virtual topology diagrams, which helps users understand key data in the power system; the hierarchical structure and filtering module allows users to view different levels and detail levels of the power system, and users can Filter the displayed devices and connections as needed; the navigation and interactive tool module is used to navigate in the topology map, including zooming, panning and selecting specific devices. These tools increase the user's operability of the topology map; the virtual topology analysis module provides some Analysis tools to help users evaluate power system performance and stability. This can include load flow analysis, short circuit analysis, and voltage stability analysis.

The power system topology module cooperates with these sub-modules to help users visualize the structure, layout and topological relationships of the power system. Users can better understand the components and interconnectivity of the power system through the power system topology module.

The real-time monitoring and data visualization module consists of data collection and transmission unit, data storage and management unit, real-time monitoring interface unit, data analysis and alarm unit, data visualization tool unit, custom dashboard and chart unit, historical data query and review unit, It consists of a real-time map view unit, a multi-screen support unit, a real-time notification and communication unit, and a data export and sharing unit.

The data acquisition and transmission unit is responsible for collecting real-time data from various power equipment and sensors, such as current, voltage, frequency, temperature, etc. It also includes a data transmission protocol for transmitting data to the monitoring system; the data storage and management unit is used to Store large amounts of real-time data, usually in a database. This gives users access to historical data for review and analysis; a real-time monitoring interface unit, which provides a user interface for viewing real-time data; this can include dashboards, charts, graphs, and map views to showcase various aspects of the power system; Data Analysis and alarm units are used to detect anomalies and trends. If the system detects a problem, it can generate an alarm and notify the user; the data visualization tool unit is used to present real-time data in visual forms, such as charts, graphics, animations, heat maps, etc. This makes it easier for users to understand the data; the custom dashboard and chart unit allows users to customize dashboards and charts according to their needs, and users can choose to display parameters and data of interest; the historical data query and review unit provides users with access to historical data With the ability to understand past performance and events, users can query and review past data records; the real-time map view unit, if the power system involves geographical information, can display the geographical location and equipment distribution of the power system, and users can view it on the map View real-time data; the multi-screen support unit allows users to extend the real-time monitoring interface to multiple displays to view more data and graphics; the real-time notification and communication unit can notify users through multiple communication methods, such as email, SMS, Notification applications and more; the data export and sharing unit allows users to export real-time data for further analysis or to share with other users. The data can be exported in various formats such as CSV, Excel or PDF.

These units work together to enable users to monitor various parameters and data in the virtual power system in real time and visualize these data in an intuitive way to better understand the performance and status of the power system.

The power equipment management module consists of equipment ledger and database, equipment status monitoring unit, equipment control and operation unit, equipment performance analysis unit, equipment maintenance plan and calendar unit, standby equipment management unit, equipment health monitoring unit, equipment report and log unit, It is composed of remote monitoring and operation unit, security and authority control unit.

Equipment ledgers and databases are used to record and manage equipment information in the power system, including equipment name, model, manufacturer, rated parameters, installation date, etc. Usually, this information is stored in the database for quick retrieval and query; equipment The status monitoring unit is used to monitor the operating status of power equipment in real time, including switching status, temperature, current, voltage, etc. If there is a problem or abnormality in the equipment, this module can generate an alarm or notify operation and maintenance personnel; the equipment control and operation unit allows users to Remote or local control of power equipment, such as starting and stopping generators, switching switches, adjusting transformer parameters, etc., which requires the equipment to support remote control or automated control; the equipment performance analysis unit provides tools to analyze the performance and efficiency of the equipment to detect any potential problems or signs of maintenance needs, including vibration analysis, energy efficiency assessment and equipment life prediction; equipment maintenance plan and calendar unit, allowing users to formulate and manage equipment maintenance plans, including maintenance cycles, maintenance types, maintenance records, etc., this unit can generate Maintenance reminders and plans; the standby equipment management unit is used to manage standby equipment, such as standby generators, standby transformers, etc., including its status, availability and automatic switching control; the equipment health monitoring unit uses sensors and monitoring data to evaluate the health of the equipment situation. It can detect vibration, temperature, oscillation and other indicators to detect potential problems in advance; the equipment reporting and logging unit provides functions that allow users to generate equipment performance reports, maintenance logs and event records. These reports can help operation and maintenance personnel track the history of the equipment. performance and problem resolution; the remote monitoring and operation unit allows operation and maintenance personnel to access and operate power equipment from remote locations, which can improve the efficiency and response speed of operation and maintenance; the security and permission control unit is used to ensure that only authorized users can Access and operate device management modules to maintain power system security.

Through the collaborative work of these units, managers and operation and maintenance personnel can monitor, manage and maintain various equipment in the power system in real time to ensure their normal operation and efficient performance.

The energy market module consists of market design and rules, market participants, market trading platform, electricity price formation, supply and demand simulation, market analysis tools, market simulation parameter settings, market result reporting and analysis, and market transaction history storage, as follows:

Market design and rules: This unit is responsible for defining and simulating the design and rules of the electricity market, including market type (bidding, pricing), bidding rules, settlement rules, market participants, etc.;

Market participants: including various market participants such as power producers, distributors, retailers, end users and market regulators, this unit simulates their behaviors and strategies;

Market trading platform: a platform used to simulate market transactions, including electronic trading systems, order books, transaction records and settlement systems. This unit handles transactions between market participants;

Electricity price formation: used to simulate the formation process of electricity prices, including the price of ancillary services, peak and valley electricity prices, market clearing prices, etc., which affects the price of market transactions;

Supply and Demand Simulation: This unit simulates the supply and demand balance of electricity markets, including electricity supply, demand, energy storage and transmission losses, which helps determine market prices and reliability of electricity supply;

Market analysis tools: Provide tools to analyze market data and trends, including market prices, trading volumes, market shares, competition, etc., which help market participants formulate strategies;

Market simulation parameter setting: used to set parameters for market simulation, such as market rules, market cycle, market capacity, etc., which allows users to customize simulation conditions;

Market result reporting and analysis: Provide tools to generate market result reports, including market transaction records, settlement results, market performance analysis, etc.;

Market transaction history storage: Store and manage historical market transaction data for backtesting and market analysis.

All aspects of the electricity market can be simulated and managed through the energy market module to help market participants understand market operations, optimize strategies and make decisions.

The social interaction and collaboration module consists of user management and permission control unit, user profile and social network unit, real-time chat and instant messaging unit, knowledge base and document management unit, notification and reminder unit, user evaluation and feedback unit, virtual meeting and video It is composed of conference unit, user analysis and statistics unit, as follows:

User management and permission control unit: used to manage user accounts, roles and permissions to ensure that only authorized users can access and participate in social interactions;

User Profiles and Social Networking Unit: allows users to create and manage personal profiles and establish social networks in order to connect and interact with other users;

Live Chat and Instant Messaging Unit: Provides instant messaging tools for users to conduct one-to-one or many-to-many real-time chats and discussions;

Knowledge base and document management unit: used to create, store and share documents, guides and knowledge bases so that users can access and share information;

Notifications and reminders unit: allows users to set reminders, notifications and event reminders to ensure they don't miss important information and events;

User evaluation and feedback unit: Provides a user evaluation and feedback mechanism so that users can evaluate the contributions of other users and provide feedback;

Virtual Meetings and Video Conferencing Unit: This unit allows users to schedule and participate in virtual meetings, video conferencing and online seminars;

User Analytics and Statistics Unit: used to analyze user interactions, social network activity and content sharing to provide insights and improve functionality.

Together, these units form social interaction and collaboration modules to promote communication, cooperation, and information sharing among users, thereby enhancing user experience and knowledge transfer.

The Virtual Training and Simulation module consists of Course Management and Course Creation, Virtual Training Environment, Multimedia Content, Interactive Quizzes and Quizzes, Virtual Labs, Simulation Consoles and Tools, Performance Evaluation and Feedback, Progress Tracking and Reporting, Virtual Scenarios and Cases, Social Interaction and collaboration, virtual tutors and support, user analysis and statistics are composed of the following:

Course management and course creation: used to manage training courses, create course content and schedule training activities;

Virtual training environment: Provides a virtual environment that allows users to conduct training and simulated operations in simulated power systems;

Multimedia content: Provide a variety of multimedia content such as videos, teaching materials, demonstrations and interactive courses to support virtual training;

Interactive quizzes and quizzes: Allow users to take interactive quizzes, quizzes and exams to evaluate training effectiveness;

Virtual laboratory: Provides a virtual laboratory environment that allows users to simulate and experiment with various power system operations and scenarios;

Simulation Consoles and Tools: Used to simulate power system consoles, monitors and tools for simulation operations;

Performance evaluation and feedback: Provides a feedback mechanism to evaluate user performance and provide suggestions for improvement;

Progress Tracking and Reporting: Allows managers to track users’ training progress and generate reports to evaluate overall training effectiveness;

Virtual Scenarios and Cases: Provides different virtual scenarios and cases to cover various power system operations and emergency situations;

Social interaction and collaboration: allows users to communicate, collaborate and discuss training content with each other;

Virtual tutors and support: Provide virtual tutors, online support and help documentation to assist users in learning and solving problems;

User analysis and statistics: used to analyze user learning data and performance to improve training content and methods.

The virtual training and simulation modules constitute a virtual training and simulation module that enables power system operators and learners to conduct actual operations, training and simulation exercises through a virtual environment to improve their skills and knowledge levels.

By integrating Metaverse technology into power system management, the present invention provides an innovative, highly integrated platform to improve the visualization, training and decision support of the power system, thereby improving the efficiency and reliability of the power system.

Although the embodiments of the present invention have been shown and described, those of ordinary skill in the art will understand that various changes, modifications, and substitutions can be made to these embodiments without departing from the principles and spirit of the invention. and modifications, the scope of the invention is defined by the appended claims and their equivalents.

Claims (8)

1. A new power system display platform based on the Metaverse, which is characterized by: Virtual power system environment, a virtual environment used to simulate the power system; The power system environment includes a three-dimensional modeling and scene generation module, a virtual map and geographical information system module, a user interface and interaction module, a physics engine module, a ray tracing and rendering module, a virtual equipment and energy generation module, virtual sensors and data collection module, virtual market and economic system module, virtual fault module and emergency response module, data export and report generation module; The power system topology module is used to display the topology of the power system; Real-time monitoring and data visualization module for providing real-time data and presenting data in a visual way; Power equipment management module, used to manage power equipment and monitor its status and performance; Load management and forecasting module for load optimization and distribution; The load management and prediction module consists of a historical load data collection module, a real-time load data collection module, a load prediction algorithm, a load prediction model, a load analysis tool module, a load balancing strategy module, a load adjustment and control module, a load management report module and an instrument It consists of disk, user demand forecast and load forecast error analysis modules; Energy market module, used to display energy market prices and related data; Fault simulation and crisis management module for simulating power system fault and crisis situations; The fault simulation and crisis management module consists of a fault situation setting module, a fixed simulation module, a real-time monitoring and response module, an emergency response plan module, a simulated event recording module, a crisis management tool module, a simulation result analysis module, a drill and training module, Composed of communication and collaboration tool modules, security and permission control modules; Decision support tools to assist users in making decisions; The decision support tools include data collection and integration units, data analysis tools, decision support systems, multi-criteria decision analysis units, decision tree and scenario analysis units, risk assessment and management units, decision audit and tracking units, collaboration and team decision support unit; Social interaction and collaboration module to support multi-user interaction and collaboration; Virtual training and simulation modules for training power system operation and maintenance personnel. 2. A new power system display method based on the metaverse according to claim 1, characterized in that it includes the following steps: S1. Enter the virtual power system environment: Users enter the virtual power system environment through head-mounted VR devices; S2. View real-time data and visual presentation of the power system: Users can view real-time data of the power system through the interface in the virtual environment, including but not limited to grid load, frequency and voltage, as well as visual graphics to present these data; S3. Simulate different scenarios and decisions of the power system: Users can use tools in the virtual environment to simulate different scenarios; S4. Collaborate and interact socially with other users: Multiple users can interact and collaborate in the same virtual power system environment to solve problems and make decisions together; S5. Train power system operation and maintenance personnel to simulate various situations: Users can use the virtual environment to train power system operation and maintenance personnel, allowing them to simulate a variety of situations, including but not limited to responding to faults, emergencies, and maintenance operations. 3. A new power system display platform based on the Metaverse according to claim 1, characterized in that the power system topology module consists of a geographical information system integration module, a power equipment element library module, a virtual map and a terrain module. , topology editing tool module, automatic topology generation module, label and information display module, power flow and load distribution module, hierarchical structure and filtering module, navigation and interactive tool module, and virtual topology analysis module. 4. A new power system display platform based on the Metaverse according to claim 1, characterized in that the real-time monitoring and data visualization module consists of a data acquisition and transmission unit, a data storage and management unit, and a real-time monitoring interface unit. , data analysis and alarm unit, data visualization tool unit, custom dashboard and chart unit, historical data query and review unit, real-time map view unit, multi-screen support unit, real-time notification and communication unit, data export and sharing unit. 5. A new power system display platform based on the Metaverse according to claim 1, characterized in that the power equipment management module consists of an equipment ledger and database, an equipment status monitoring unit, an equipment control and operation unit, an equipment It is composed of performance analysis unit, equipment maintenance plan and calendar unit, backup equipment management unit, equipment health monitoring unit, equipment reporting and logging unit, remote monitoring and operation unit, security and authority control unit. 6. A new power system display platform based on the Metaverse according to claim 1, characterized in that the energy market module consists of market design and rules, market participants, market trading platform, electricity price formation, supply and demand simulation, It consists of market analysis tools, market simulation parameter settings, market result reporting and analysis, and market transaction history storage. 7. A new power system display platform based on the Metaverse according to claim 1, characterized in that the social interaction and collaboration module consists of a user management and authority control unit, a user profile and social network unit, a real-time chat It is composed of instant messaging unit, knowledge base and document management unit, notification and reminder unit, user evaluation and feedback unit, virtual meeting and video conferencing unit, user analysis and statistics unit. 8. A new power system display platform based on the Metaverse according to claim 1, characterized in that the virtual training and simulation module consists of course management and course creation, virtual training environment, multimedia content, interactive tests and tests , virtual labs, simulation consoles and tools, performance evaluation and feedback, progress tracking and reporting, virtual scenarios and cases, social interaction and collaboration, virtual mentors and support, user analytics and statistical components.