The Polar Bear Energy Management System is mainly designed for enterprise, factory, commercial building, city, and community scenarios. It monitors, records, analyzes, and evaluates the consumption process data of water, steam, natural gas, and electricity in enterprises and factories. It provides a clear and scientific basis for energy conservation and efficiency improvement by monitoring detailed energy consumption across various aspects of the enterprise in real-time. The system helps identify energy consumption weak points, enhance management capabilities, and reduce operational costs. It promotes rational energy usage, waste control, and achieves energy conservation, emission reduction, and improved profitability. Through data analysis, it enables enterprises to assess each production line, work team, and major energy-consuming equipment in real-time, eliminate waste, and optimize processes to reduce energy consumption costs and improve overall competitiveness. The development and application of the energy management system represent a new concept for production management, measurement management, and energy-saving management for enterprises, offering an effective solution for achieving energy conservation, emission reduction, and energy efficiency improvement.

In addition to reliability, flexibility, compatibility, and high efficiency, the energy management system can also help enterprises improve their energy information management, optimize energy management processes, reduce energy system operating costs, and speed up the handling of energy system faults and anomalies. It can assist enterprises, factories, institutions, and communities in achieving effective energy consumption control and management, reducing energy expenditure, and improving energy utilization efficiency.

1. Improve the acquisition, storage, management, and utilization of energy information: With a comprehensive energy information acquisition system, first-hand operating process data can be easily obtained, providing real-time updates on the system's operation status and allowing timely scheduling measures to be taken to ensure that the system runs at its optimal state, while minimizing the impact of accidents. Under the guidance of the enterprise energy management department, the energy system is controlled in a decentralized manner and managed centrally. To meet the characteristics of decentralized energy process systems and centralized energy management requirements, an energy management system can be established to adapt to the strategic development needs of the enterprise.

2. Streamline energy management processes and establish an objective energy consumption evaluation system: The construction of an energy management system can realize process optimization and transformation of energy monitoring and energy management based on information analysis, achieve effective energy equipment and operation management, objectively based on data, evaluate energy consumption, performance assessment, reduce energy management costs, improve energy management efficiency, and promptly understand real energy consumption situations and propose energy-saving and consumption reduction techniques and management measures to seek benefits from energy management.

3. Reduce energy system operating and management costs and increase labor productivity: Large enterprises have larger energy system scales and complex structures. Traditional on-site management, operation, maintenance, and management require significant labor resources and are costly. The establishment of an energy center will play an important demonstrative role in the reform of the enterprise's management system. Although small and medium-sized enterprises may have fewer measurement points, energy management will be more intuitive and effective. The ultimate goal of the system is to achieve remote meter reading and unified monitoring, simplify energy operation and management, reduce daily management manpower input, save labor resource costs, and increase labor productivity.

4. Accelerate energy system fault and anomaly handling and improve the enterprise's performance in response to energy accidents: Energy dispatching can quickly understand the global operation status of the system, identify fault points and take appropriate measures to reduce losses. This is particularly effective in non-normal situations in energy management systems. By optimizing energy dispatching and balancing command systems, energy can be saved and the environment improved. The construction of an energy management system will improve the technical means of improving energy balance through optimized energy management methods and techniques, and realize real-time understanding of enterprise energy demand and consumption, providing conditions for further digging, analyzing, processing, and handling energy data. Data is wealth, and data can become information, which will provide possibilities for enterprise's high-end energy management. As seen from above, the building of an energy management system can improve the level of energy system operation and management, reduce energy consumption, improve energy supply quality, strengthen and improve energy assessment and evaluation systems, increase labor productivity, improve environmental quality, and enhance the market competitiveness of enterprise products, all of which have good effects and results.

System Architecture Design

An energy management system is a tool used to monitor and control energy consumption. Its main purpose is to reduce energy consumption, improve the economic benefits and social responsibility of enterprises by collecting, visualizing, and analyzing data from various energy devices within the enterprise. The three core functions of an energy management system are energy consumption data collection, visualization, and analysis.

Functional Architecture Design

As an important tool within the enterprise, an energy management system needs to meet strong operational requirements and complex technical requirements. Therefore, it has four major standard systems: energy ecological system, operation service system, network security assurance system, and standard specification system.

The energy ecological system refers to the management system of the energy management system in terms of strategic positioning, goal planning, demand identification, resource integration, etc. It realizes micro-control and macro-regulation of energy consumption through the construction and optimization of the ecological system.

The operation service system manages various services and processes for the operation of the energy management system, including engineering design, equipment monitoring, maintenance services, energy supply, and operation management, ensuring the stable, efficient, and safe operation of the system.

The network security assurance system mainly includes measures such as network data defense, data encryption, data backup, and recovery, aiming to improve system stability and security, and ensuring the privacy, integrity, and confidentiality of internal data.

The standard specification system is responsible for formulating and updating system standards and specifications, making the system more regulated and standardized, thereby improving its reliability, stability, and security.

Real-time Energy Monitoring

Real-time energy monitoring refers to the continuous online monitoring of various devices and measurement points in the field of energy, and presenting the data in the form of bar charts and statistical tables in real time, making it convenient for users to view and manage energy usage. The monitoring data can be statistically analyzed based on daily, monthly, yearly, and other periods, and the system can generate real-time alerts for abnormal situations, reminding users to take timely actions to ensure the normal operation of the equipment and improve energy efficiency.

Energy Consumption Statistical Analysis

Energy consumption statistical analysis refers to the monitoring, collection, analysis, and evaluation of various energy consumption situations, in order to scientifically analyze and evaluate energy usage efficiency, consumption composition, emissions, etc. It helps identify energy usage bottlenecks and issues, and propose improvement solutions, thus achieving the goal of reducing energy consumption and improving efficiency.

Energy Type Analysis

Energy type analysis involves classifying, counting, comparing, evaluating, and predicting different types of energy to comprehensively understand the consumption composition of various energy sources. It can cover multiple types of energy, including electricity, natural gas, steam, water, etc.

Energy Cost Analysis

Energy cost analysis involves statistical analysis and evaluation of energy usage in enterprises or factories, in order to identify and implement energy-saving measures, reduce energy costs, and provide a basis for future energy consumption and budget planning.

Peak-Valley Load Statistics

For the energy consumption statistics during peak and off-peak periods, comprehensive analysis can be conducted based on various key factors such as time, location, industry, user type, energy consumption, etc. It can also compare and predict data from various aspects including weather information and socioeconomic development to better plan and allocate energy resources.

Energy Reports

Energy reports include key indicators such as energy consumption, unit energy consumption, and energy costs. The data can be classified and summarized according to different types of energy. These data are presented through charts, tables, and text, reflecting the situation and trends of energy usage in enterprises or organizations in a visual manner.

Metering Instruments

Energy metering instrument management involves a series of work related to the allocation and use management of energy metering instruments. It ensures the accuracy, reliability, and safety of energy metering data, providing scientific basis for energy conservation and reducing energy consumption.

1. Enterprise and Factory Energy Management

An energy management system can monitor and digitally manage the consumption of energy sources such as electricity, water, gas, and heat in real time. It helps enterprise managers grasp the real-time energy usage and conduct data analysis to optimize production processes, reduce energy consumption, and improve energy utilization efficiency.

2. Commercial Building Energy Management

Commercial buildings, including shopping malls, office buildings, hotels, etc., have high energy consumption and complex management requirements. An energy management system can help management institutions monitor energy consumption in real time, classify and analyze energy sources, identify key areas and vulnerabilities in energy usage, and provide feasible suggestions to achieve energy savings and reduce operating costs.

3. Urban Energy Management

Urban energy management is a centralized energy supply model based on the energy internet and big data technology. It enables efficient scheduling and intelligent control of urban energy. An energy management system plays a critical role in urban energy management by collecting, calculating, and analyzing data from various energy sites, comprehensively managing and optimizing urban energy, and improving energy utilization efficiency and operational quality.

4. Community Energy Management

Communities are one of the basic units of urban energy consumption. An energy management system can be implemented in neighborhoods or streets through smart metering and information sensing devices. It collects and analyzes residents' energy consumption data, enables centralized control of energy usage, effectively manages community energy consumption, and supports services such as billing and energy-saving promotion.