红外技术
紅外技術
홍외기술
INFRARED TECHNOLOGY
2015年
4期
300-304
,共5页
徐金凤%张玉钧%何莹%尤坤%高彦伟
徐金鳳%張玉鈞%何瑩%尤坤%高彥偉
서금봉%장옥균%하형%우곤%고언위
物理光学%C-Lens%ZEMAX%耦合效率
物理光學%C-Lens%ZEMAX%耦閤效率
물리광학%C-Lens%ZEMAX%우합효솔
physical optics%C-Lens%ZEMAX%coupling efficiency
基于光谱吸收法的瓦斯实时监测系统的核心器件是开放式光学吸收池,根据矩阵传输理论和q参数的ABCD法则,设计了由2个相对的C-Lens组成的光学吸收池结构,并在ZEMAX的物理光学模式下实现仿真与优化。由理论分析得到结构的初步参数并在ZEMAX中进行优化,并使用合适的优化操作数对像差进行校正,经过逐步优化得到工作距离为100.39 mm的吸收池结构参数。高斯光束从一端光纤输出的束腰半经为5.2?m,经C-Lens聚焦和准直后,耦合到另一端光纤的束腰半经为5.48?m,该光学吸收池对甲烷近红外激光的耦合效率达到92%。通过实验验证了该光学吸收池的稳定性和高耦合效率,适用于甲烷气体的开放式光学气体传感和在线监测。
基于光譜吸收法的瓦斯實時鑑測繫統的覈心器件是開放式光學吸收池,根據矩陣傳輸理論和q參數的ABCD法則,設計瞭由2箇相對的C-Lens組成的光學吸收池結構,併在ZEMAX的物理光學模式下實現倣真與優化。由理論分析得到結構的初步參數併在ZEMAX中進行優化,併使用閤適的優化操作數對像差進行校正,經過逐步優化得到工作距離為100.39 mm的吸收池結構參數。高斯光束從一耑光纖輸齣的束腰半經為5.2?m,經C-Lens聚焦和準直後,耦閤到另一耑光纖的束腰半經為5.48?m,該光學吸收池對甲烷近紅外激光的耦閤效率達到92%。通過實驗驗證瞭該光學吸收池的穩定性和高耦閤效率,適用于甲烷氣體的開放式光學氣體傳感和在線鑑測。
기우광보흡수법적와사실시감측계통적핵심기건시개방식광학흡수지,근거구진전수이론화q삼수적ABCD법칙,설계료유2개상대적C-Lens조성적광학흡수지결구,병재ZEMAX적물리광학모식하실현방진여우화。유이론분석득도결구적초보삼수병재ZEMAX중진행우화,병사용합괄적우화조작수대상차진행교정,경과축보우화득도공작거리위100.39 mm적흡수지결구삼수。고사광속종일단광섬수출적속요반경위5.2?m,경C-Lens취초화준직후,우합도령일단광섬적속요반경위5.48?m,해광학흡수지대갑완근홍외격광적우합효솔체도92%。통과실험험증료해광학흡수지적은정성화고우합효솔,괄용우갑완기체적개방식광학기체전감화재선감측。
The core device of gas absorption spectroscopy real-time monitoring system is open optical absorption cell. According to the transmission matrix theory and ABCD rule ofqparameter, optical absorption cell structure composed of two opposing C-Lensis designed, and its simulation and optimization is realized under ZEMAX physical optics model. Preliminary parameters obtained from the theoretical analysis of the structure are optimized in ZEMAX, and the suitable optimization function is used for correcting aberration and to get parameters of absorption cell structure with a working distance of100.39cmafter gradually optimization. Gaussian beam waist radius from one end of the fiber output as 5.2?m, after C-Lens focusing and collimating, is coupled to the other end of the fiber output with waistradius of 5.48?m, and the coupling efficiency of optical absorption cell for methane near-infrared laser is up to 92%. Experiments show the stability of the optical absorption cell and a high coupling efficiency, which is suitable for methane gas open optical gas sensing and online monitoring applications.
