【中文介紹】
Hukseflux LP02-TR 二級總輻射傳感器是一款專業級太陽輻射測量設備,適用于環境監測、氣象研究、農業氣象及可再生能源系統監測等領域。該產品采用熱電堆原理設計,可精確測量波長范圍在300至3000 nm的全波段太陽總輻射,為科研和工程應用提供可靠數據支持。
傳感器主體采用耐候性陽極氧化鋁材質外殼,內部配置雙層散射層設計,有效降低余弦響應誤差。獨特的防塵防水結構達到IP67防護等級,配合溫度補償電路設計,可在-40℃至+80℃環境下保持測量穩定性。水平校準底座支持快速安裝定位,標配輻射通風罩有效減少外部環境對測量結果的干擾。
在數據輸出方面,提供4-20mA模擬信號與Modbus RTU數字接口雙模輸出,兼容多數數據采集系統。產品經過嚴格實驗室校準和戶外長期穩定性測試,在日累計輻射量測量中表現出±3%的測量精度,特別適用于光伏電站效率評估、溫室氣候調控等需要連續監測的場景。
【English Introduction】
The Hukseflux LP02-TR Secondary Standard Pyranometer is a professional-grade solar radiation measurement instrument designed for environmental monitoring, meteorological research, agricultural meteorology, and renewable energy system applications. Utilizing thermopile detection technology, this sensor accurately measures total solar irradiance within the 300-3000 nm wavelength range, delivering reliable data for both scientific research and engineering projects.
Constructed with weather-resistant anodized aluminum housing, the device incorporates dual-layer diffusion technology to minimize cosine response errors. Its IP67-rated waterproof structure combined with precision temperature compensation ensures stable operation across extreme temperatures from -40℃ to +80℃. The integrated leveling base enables rapid installation alignment, while the optional ventilation unit effectively reduces measurement interference from environmental factors.
Featuring dual-output modes with 4-20mA analog signal and Modbus RTU digital interface, the sensor demonstrates seamless compatibility with most data acquisition systems. Through rigorous laboratory calibration and extended field validation, the instrument achieves ±3% daily irradiation measurement accuracy, making it particularly suitable for photovoltaic system performance evaluation and greenhouse climate management applications requiring continuous monitoring.
The streamlined design emphasizes low maintenance requirements, with detachable cable connectors simplifying field deployment. Optimized thermal mass design ensures rapid response to irradiance variations while maintaining measurement consistency under fluctuating ambient conditions.
