The role of microgrids in ensuring safe and reliable power supply in the region has been highly recognized by the industry and society. Distributed microgrids have outstanding advantages, but their control is difficult. Therefore, smart microgrids are widely promoted and applied. According to the project characteristics of distributed sites, WideIOT has many successful cases and a complete set of solutions from on-site data collection to platform application.

With the continuous increase in distributed photovoltaic power stations, their operation and management face numerous challenges. For instance, the scattered distribution of stations makes manual inspections difficult and costly; real-time monitoring of equipment status is challenging, leading to delayed fault detection and resolution. To enhance the power generation efficiency of distributed photovoltaic power stations, reduce operational and maintenance costs, and ensure stable system operation, an advanced photovoltaic monitoring and management system is required.

Wind farms are typically located in remote areas, featuring numerous wind turbines spread across vast expanses. Traditional management methods struggle to provide real-time, comprehensive monitoring and maintenance for these turbines. Turbine operation is influenced by various factors, including weather conditions, and equipment failures can lead to power generation interruptions and economic losses. To enhance operational efficiency, reduce maintenance costs, and maximize the utilization of wind energy resources, a comprehensive wind farm monitoring and management system is essential.

As a critical component of the power supply chain, the safe and stable operation of distribution substations is of paramount importance. With the continuous growth in electricity demand and the expansion of grid scale, the increasing number and complex structure of substation equipment make traditional manual inspection and monitoring methods inadequate for real-time, comprehensive surveillance. Equipment failures can lead to power outages, disrupting normal electricity supply to users. To enhance the reliability and safety of distribution substations, an intelligent monitoring system is required.

In order to realize real-time dynamic monitoring of oilfields, provide accurate data basis for production operation and management decisions, and comprehensively improve the level of safety management, many customers urgently need to build oilfield IoT systems.WideIOT focuses on the overall solution of the Internet of Things, and has corresponding independent research and development products from on-site data collection to the platform, which can meet the various needs of customers for building oilfield systems.

With the continuous expansion of campus and building scales, energy consumption is also increasing. Traditional energy management methods lack refinement and intelligence, making it impossible to effectively reduce energy costs and improve energy utilization efficiency. To achieve energy conservation and emission reduction goals, lower operating costs, and enhance the energy management level of campuses and buildings, an advanced energy management system is required.

In the industrial and commercial sector, there are high requirements for the reliability of power supply and cost control. Meanwhile, with the widespread application of photovoltaic, energy storage and charging facilities, how to achieve efficient coordination and optimized management of these energy devices has become a key issue. Traditional management methods are unable to meet the needs of integrated management of multiple energy devices, and cannot give full play to the comprehensive benefits of the energy system. To improve industrial and commercial energy utilization efficiency, reduce electricity costs and ensure the stability of power supply, an integrated PV-storage-charging (EMS) monitoring system is required.

With the popularization of electric vehicles, the number of charging piles is constantly increasing. Charging piles are widely and dispersedly distributed, making it difficult for traditional management methods to conduct real-time monitoring and effective maintenance of them. Charging pile faults may prevent users from charging normally and affect user experience. To improve the operational efficiency of charging piles, ensure the quality of charging services, and reduce operation and maintenance costs, a remote monitoring and management system is required.