IOT News

Photovoltaic greenhouses, as an innovative combination of photovoltaic energy utilization and agricultural production, have their power generation efficiency and operation and maintenance quality directly related to the output benefits of clean energy and agricultural production revenue. They are crucial infrastructure for promoting rural industrial integration and achieving green and sustainable development. Meanwhile, they also pose increasingly higher requirements for equipment manufacturers.

In the traditional model, photovoltaic greenhouses mostly adopt decentralized manual operation and maintenance. Equipment status and operational data are stored locally in an isolated manner, lacking unified information integration and remote control means. This leads to issues such as resource scheduling relying on empirical judgment, delayed equipment fault diagnosis, and non-standardized operation and maintenance processes. These problems increase the operating costs of enterprises and restrict the large-scale promotion and efficient operation of photovoltaic greenhouses, becoming a significant obstacle to the industrial upgrading of the "photovoltaic + agriculture" sector.

WideIOT takes the "industrial gateway + equipment operation and maintenance management platform" as its core. By comprehensively connecting to the photovoltaic power generation systems (inverters, smart meters, sensors, etc.) in photovoltaic greenhouses, it achieves real-time collection, cleaning, and integration of power generation data, environmental data, and equipment operation data. This builds a unified smart operation and maintenance management system for photovoltaic greenhouses, enabling centralized, intelligent, and efficient operation and maintenance management of photovoltaic greenhouses, maximizing the dual benefits of power generation and after-sales service, and facilitating high-quality industrial development.

Implemented Functions

Real-time Monitoring: Monitor core data of the photovoltaic system (such as component power generation, inverter operating status, voltage and current, power factor) and on-site environmental parameters (such as temperature and humidity, light intensity) in real time to ensure stable power generation efficiency and suitable planting environments.

Equipment Health Tracking: Track the operating hours, working status, energy consumption data, and fault records of core equipment, establish an equipment health assessment model, and enable predictive maintenance and precise overhauls to reduce unplanned downtime.

Multi-level Alarming: When the system experiences abnormalities, the platform immediately triggers multi-level alarms (via SMS, WeChat, email, etc.), clearly indicating the abnormal location, cause analysis, and disposal suggestions for rapid response and problem-solving.

Standardized Operation and Maintenance Management: Establish a standardized operation and maintenance management system that supports the automatic creation, intelligent allocation, progress tracking, and closed-loop management of operation and maintenance work orders, as well as recording the entire process of work order handling and consumable usage.

Multi-dimensional Visual Data Dashboard: Create a multi-dimensional visual data dashboard that centrally displays information such as the greenhouse distribution map, real-time power generation, equipment health status, alarm statistics, completion rate of operation and maintenance work orders, and calculation of power generation and planting benefits, providing intuitive and scientific data support for management decision-making.