Negative Oxygen Ion Monitoring Station in Scenic Area

The Scenic Area Negative Oxygen Ion Monitoring Station is a real-time environmental meteorological monitoring and reporting system designed for forestry, scenic areas, parks, environmental protection, meteorology, agriculture, and related fields. Primarily focused on centralized monitoring and management of air quality environments in scenic areas and humidity parks, it functions as an automated monitoring system capable of unattended, 24/7 continuous real-time monitoring and recording.

The system monitors and records air quality across large areas, transmitting data in real-time to a PC. Utilizing system monitoring software, it stores and analyzes data, outputs historical data and trend graphs for printing, and supports on-site audible/visual alarms, telephone alerts, SMS notifications, and web client alerts.

The scenic area negative oxygen ion monitoring station can simultaneously monitor multiple environmental factors and can be expanded or reduced according to user requirements. It transmits data from the monitored environment 24 hours a day, all year round. Its unique modular structure design allows for interchangeable sensors. It comes standard with professional mounting brackets, enabling installation on walls or columns, making subsequent operation and maintenance extremely convenient.

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• Users can view and analyze data through management software, and archive or print charts and reports.

• LCD display provides real-time air quality readings at a glance.

• Digital signal output with RS485 communication interface. Multiple communication methods can be expanded as needed, such as Wi-Fi or GPRS transmission.

• Output control functions can be expanded as required. The air quality monitoring system integrates seamlessly with park misting systems to enable shared data display. The monitoring system can operate independently alongside misting systems or achieve linked, intelligent control with them.

• The entire unit incorporates lightning protection design, minimizing damage risks in thunderstorm-prone areas.

• This system enables unattended operation, continuously collecting and recording air quality changes at monitoring points 24/7. It displays and stores monitoring data in real-time through digital, graphical, and image formats. The monitoring network can be expanded to include thousands of points.

• Upper and lower alarm thresholds can be set for each monitoring point. When abnormal data occurs at a monitored point, an alarm signal is automatically triggered. Alarm methods include: on-site multimedia audio, audible/visual alarms, network client alerts, and mobile text messages. Alarm information is uploaded for both local and remote monitoring, enabling the system to notify different on-duty personnel at different times.

• The air quality monitoring software features a standard Windows graphical interface with full Chinese support. It displays and records real-time air quality values and trend curves for each monitoring point, while also compiling historical data, maximum/minimum values, averages, and cumulative statistics for monitored quality parameters.

• The system supports expansion with various data analysis and processing software, enabling bar chart and pie chart generation, curve fitting, and other operations. Data can be exported in TEXT format or imported into Office software like Excel for further processing.

• Powerful data processing and communication capabilities utilize computer network communication technology, enabling any computer within the local area network to access the monitoring computer. This allows online viewing of air quality changes at monitoring points, achieving remote monitoring.

• The control software is developed using software engineering management principles, ensuring high openness and scalability. Adopting a system design philosophy that software-enables hardware functions, along with modular hardware and networked communication architecture, allows for flexible software upgrades and hardware expansion as needed.

• The system design incorporates reserved interfaces, allowing hardware devices to be added or removed at any time with minimal modifications to the system, enabling completion within a short timeframe.

• All systems feature reliable grounding to prevent electrostatic discharge.

• The system employs single-channel and multi-channel bus wiring, significantly reducing wiring labor, material usage, and project costs. Furthermore, digital signals eliminate transmission errors or signal loss.