How do Distributed Operating Power Supplies Address Power Supply Pain Points of Decentralized Equipment Across Key Fields?

As equipment in fields such as power, industry, and construction gradually upgrades toward "decentralization and intelligence," the problems of traditional centralized operating power supplies—such as complex wiring and significant impact from single-point failures—have become increasingly prominent. Distributed operating power supplies, with their characteristics of "proximal power supply, flexible deployment, and independent operation," have become the core solution to address the power supply pain points of decentralized equipment. Currently, they are widely used in power distribution terminals, industrial automation, smart buildings, new energy stations, and other fields, providing reliable energy support for decentralized equipment.

Power Distribution Terminal Field: Adapting to Decentralized Sites, Simplifying Wiring and O&M

Terminal equipment in power distribution systems—such as ring main units and box-type substations—are often distributed outdoors or on different floors. Centralized power supplies require long-distance wiring, which not only increases construction difficulty but also easily affects power supply quality due to line losses. Distributed operating power supplies can be installed nearby terminal equipment, eliminating the need for complex wiring and significantly reducing construction and subsequent operation & maintenance (O&M) costs. Meanwhile, each power supply unit operates independently; a failure of one unit will not affect the power supply of other equipment, avoiding regional power distribution interruptions caused by single-point issues and improving the overall reliability of the power distribution system.

Industrial Automation Field: On-Demand Power Supply, Ensuring Independent Equipment Operation

Equipment in industrial production lines—such as sensors, actuators, and small control modules—are distributed in different areas of the workshop and have high requirements for power supply stability. Distributed operating power supplies can be "deployed on demand" according to equipment layout, providing precise power supply for equipment in different areas and avoiding the impact of voltage fluctuations on sensitive equipment during centralized power supply. When partial adjustments are made to the production line, only the power supply units in the corresponding area need to be added or removed, without reconstructing the entire power supply system. This adapts to the "flexible adjustment" needs of industrial production and reduces downtime losses caused by equipment modification.

Smart Building Field: Matching Decentralized Loads, Optimizing Energy Management

In smart buildings, equipment such as security cameras, access control systems, and environmental monitoring devices are distributed across different floors and public areas of the building. Traditional centralized power supply struggles to cover all decentralized loads. Distributed operating power supplies can be deployed by floor and area, providing proximal power supply for various terminal equipment and reducing line energy consumption and signal interference. At the same time, the system supports linkage with the building energy management platform, enabling real-time monitoring of power supply status and energy consumption adjustment in each area, helping buildings build an "energy-saving and efficient" power supply system.

New Energy Station Field: Coping with Complex Environments, Ensuring Stable Equipment Operation

In new energy stations such as photovoltaic (PV) and wind power stations, equipment like inverters, combiner boxes, and monitoring devices are often located outdoors or in remote areas. Centralized power supply involves high wiring costs and is vulnerable to harsh environments. Distributed operating power supplies have protective properties such as temperature resistance and sandstorm resistance, enabling them to adapt to the complex working conditions of stations. By providing proximal power supply for each piece of equipment, they avoid power supply losses caused by long-distance wiring. Additionally, the independent operation design reduces the impact of a single equipment failure on the overall power supply of the station, ensuring the s`table operation of new energy power generation equipment.

Now, distributed operating power supplies are developing toward "intelligence and low-carbonization." They integrate intelligent monitoring functions to achieve fault early warning, and adopt low-power designs to further reduce energy consumption.As the "energy steward" for decentralized equipment, their features of flexible adaptation and reliable power supply will keep supporting equipment upgrades in multiple industries, and drive the transformation of power supply systems toward "high efficiency, flexibility, and stability."