气液环状流周向液膜测量传感器的优化设计

薛婷; 周策; 李卓林

doi:doi:10.3788/ope.20172512.3145

光学精密工程, 2017, 25 (12): 3145, 网络出版: 2018-01-10

气液环状流周向液膜测量传感器的优化设计

Optimum design of measuring sensor for circumference liquid film in gas-liquid annular flow

论文大纲

薛婷周策李卓林

作者单位

天津大学电气自动化与信息工程学院，天津 300072

视觉传感器环状流周向液膜有效视角优化设计 vision sensor annular flow circumference liquid films effective visual angle optimization

摘要

以气液两相环状流管道横截面的周向液膜为测量对象，采用单台高速摄像机和平面反射镜组构建了虚拟双视角的视觉传感器，并对传感器进行了优化。基于虚拟双目立体视觉原理建立虚拟双视角视觉传感器测量模型。为了尽可能增大有效拍摄视角以获得更多液膜流动信息，综合考虑视场区域、传感器尺寸、测量距离以及管道光路折射等因素，对虚拟双视角视觉传感器模型进行了分析和设计，优化了传感器模型的结构参数。理论分析及实验结果表明：优化后的虚拟双视角视觉传感器可以获得近300°的有效周向测量视角，远远优于使用单台高速摄像机进行直接拍摄。该项研究为通过双视角视觉传感器进行气液两相环状流周向液膜的实时测量提供了理论基础，对研究液膜厚度和分析环状流流动状态具有重要意义。

Abstract

By taking the circumference liquid films of cross-sectional pipe in gas-liquid two-phase annular flow for measuring objectives, a novel visual sensor with virtual two-visual angles was designed and optimized by combining a single high-speed camera and planar reflectors. Based on the virtual binocular stereo vision principle, a measurement model for visual sensor with two-visual angles was established. To maximize the effective measurement angle and to obtain much liquid film flow informations, the model of the virtual double-view vision sensor was analyzed and its structure parameters were optimized by considering the field of view, sensor size, measuring distance and the optical path refraction of the pipe. The theory analyzing and experimental results indicate that the optimized sensor can get a view field closed to 300° effective circumference visual angle, which is far better than that using a single high-speed camera to capture directly. It provides a theoretical basis for the real-time measurement of the gas-liquid two-phase annular flow circumference liquid films through the double-view vision sensor, and has great significance to study the film thickness and analyze the flow state of the annular flow.

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薛婷, 周策, 李卓林. 气液环状流周向液膜测量传感器的优化设计[J]. 光学精密工程, 2017, 25(12): 3145. XUE Ting, ZHOU Ce, LI Zhuo-lin. Optimum design of measuring sensor for circumference liquid film in gas-liquid annular flow[J]. Optics and Precision Engineering, 2017, 25(12): 3145.

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