基于光纤传感技术的路面结冰智能监测研究进展

doi:10.13229/j.cnki.jdxbgxb.20230037

摘要/Abstract

摘要：

为了促进道路安全性智能感知技术应用，对国内外有关光纤传感路面结冰状态智能监测的研究进展进行了综述。首先，揭示了光纤式路面结冰检测原理；随后，经过分析不同光纤性能指标、常用探头分布模式以及多种弱信号检测方法，构建了光纤式路面结冰检测系统；然后，探讨了常见的结冰检测数据预处理及其厚度分析方法，并概括主要环境影响因素和提升检测效果的措施，分析了适用于光纤式路面结冰检测传感器的埋设工艺；最后，归纳并总结了当前结冰路面监测及预警研究现状，论述了现有研究存在的问题并尝试对路面结冰状态智能感知的发展方向进行展望。

关键词: 道路工程, 结冰路面, 结冰传感器, 光纤技术, 智能感知

Abstract:

In order to promote the application of road safety intelligent perception technology， the research progress about intelligent monitoring of pavement icing condition based on optical fiber sensing at home and abroad was overviewed. Firstly， the principle of fiber-optic pavement icing detection was revealed. Subsequently，based on the analysis of different optical fiber performance indexes， the distribution mode of common probes and various weak signal detection methods， the fiber-optic pavement icing detection system was constructed. Then， common icing detection data pre-processing and its thickness analysis methods were explored， the main environmental influencing factors and measures to enhance detection effectiveness were outlined， and burying technology of fiber-optic road icing detection sensor was analyzed. Finally， current research status of icing pavement monitoring and early warning were summarized， the existing problems were discussed， and the development direction of intelligent sensing of pavement icing condition was attempted to outlook.

Key words: road engineering, frozen pavement, ice sensor, optical fiber technology, intelligent perception

中图分类号:

U416.214

赵晓康,胡哲,张久鹏,裴建中,石宁. 基于光纤传感技术的路面结冰智能监测研究进展[J]. 吉林大学学报(工学版), 2023, 53(6): 1566-1579.

Xiao-kang ZHAO,Zhe HU,Jiu-peng ZHANG,Jian-zhong PEI,Ning SHI. Research progress in intelligent monitoring of pavement icing based on optical fiber sensing technology[J]. Journal of Jilin University(Engineering and Technology Edition), 2023, 53(6): 1566-1579.

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指标	聚合物光纤	石英光纤
芯径/μm	100~1000	62.5
数值孔径	0.5	0.22
受光角/（°）	60	16
典型波长/nm	650	850/1300
典型损耗/（dB·km^-1）	125	3.5/1
弹性模量/GPa	3.2	72
拉伸长度/%	5~10	1~2
光源成本/＄	3~5	6~25
连接器成本/＄	0.25~5	5~25
连接时间/min	1~5	1~20

探头分布模式	应用情况	优点	缺点
同轴式	检测薄冰冰厚	灵敏度高，光纤信号响应较强	检测范围小，不能识别冰型
楔形式	检测厚冰冰厚	检测范围大，识别不同冰型	灵敏度较低，容易受光饱和现象影响
复合端面式	区分明冰、霜冰和混合冰	结合多种探头模式优势，扩大检测范围	装配和端面集成校准复杂

检测方法	检测原理	特点
带通滤波法^［41］	利用功率谱密度在信号中较窄，而噪声相对较宽的特点滤掉大部分噪声	滤波器带宽B越窄，信噪比提高越好
同步累积法^［42］	重复多次测量，使信号同相地累积起来，而噪声因其随机性相互抵消	测量次数越多，信噪比改善越明显。
相关检测法^［43］	利用相关原理，输入信号与参考信号的互相关运算达到去除噪声目的	抑制能力极强，基本滤去不同步噪声
锁定检测法^［44］	结合同步累积法和相关检测法，构成锁定放大器	抗干扰能力强，把交流信号放大变成直流信号

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