甲烷和水的水平气液两相流近红外吸收特性分析

doi:10.3964/j.issn.1000-0593(2025)06-1551-06

摘要
参考文献
相关文章 (6)

全文: PDF (4543 KB)
输出: BibTeX | EndNote (RIS)

摘要：相含率是计算水平气液两相流分相流速、压降、平均密度、产气量的一项重要参数。为解决页岩气水平井气液两相流相含率测量问题，以甲烷和水为研究对象，开展基于近红外吸收技术的水平气液两相流吸收特性研究。首先根据HITRAN、Refractiveindex数据库获取甲烷和水的全波段吸收光谱，由此分析得到甲烷和水的特征吸收峰范围；然后实验得到不同压强下甲烷和不同液面厚度水的近红外光谱图，通过分析吸收峰的位置与变化幅度确定甲烷与水的吸收特征波长分别为1 650和980 nm；最后搭建安装1 650和980 nm波长激光器水平管段实验平台，分析不同压强、气液比、返排液中有机物与总溶解性固体等因素对近红外吸收性能影响。实验结果表明，980 nm近红外光强仅受液面高度影响，且随着液面高度增加，接收端近红外光强对数值线性逐渐减小；1 650 nm近红外光强同时受水液面高度及甲烷气体压强影响，且随着液面高度、压强增大，接收端近红外光强对数值线性逐渐减小；返排液中的总溶解性固体对近红外光透过率的影响略大于有机物，增加有机物和总溶解性固体的浓度对近红外光强影响均小于6%。由此可利用980 nm近红外光测量水的液面高度变化，1 650 nm近红外光测量水和甲烷压强变化，然后根据Lambert-Beer、线性叠加定律求出页岩气水平井气液两相流相含率。

关键词：页岩气水平井；气液两相流；相含率测量；近红外吸收

Abstract：The phase holdup of gas-liquid two-phase flow in shale gas horizontal wells is an important parameter for calculating phase separation velocity, pressure drop, average density，and gas production. To solve the problem of gas-liquid two-phase flow phase holdup measurement in shale gas horizontal wells, this paper studies the absorption characteristics of horizontal gas-liquid two-phase flow based on near-infrared spectroscopy. Firstly, according to the full-band absorption spectra of methane and water obtained from HITRAN and Refractiveindex databases, the characteristic absorption peak ranges of methane and water are analyzed. Then, the near-infrared spectra of methane and water with different liquid surface thicknesses under different pressures are obtained experimentally. The position and variation range of the absorption peaks are analyzed, and the absorption characteristic wavelengths of methane and water are finally determined to be 1 650 and 980 nm, respectively. Finally, the experimental platform of horizontal tube section with 1 650 and 980 nm wavelength lasers was built to analyze the effects of different pressures, gas-liquid ratios, organic matter and total dissolved solids in the flowback fluid on the near-infrared absorption performance. The experimental results show that the 980 nm near-infrared light intensity is only affected by the liquid level height, and the logarithm of the near-infrared light intensity at the receiving end decreases linearly with the increase of the liquid level height. The near-infrared light intensity at 1 650 nm is affected by the height of the water level and the pressure of the methane gas, and as the height of the liquid level increases and the pressure increases, the logarithm of the near-infrared light intensity at the receiving end decreases linearly. The effect of total dissolved solids in the flowback fluid on the near-infrared light transmittance is slightly greater than that of organic matter. Increasing the concentration of organic matter and total dissolved solids, the effect on the near-infrared light intensity is less than 6%. Therefore, 980 nm near-infrared light can be used to measure the change in water level, and 1 650 nm near-infrared light can be used to measure the change in water and methane pressure. Then, according to Lambert-Beer and linear superposition law, the phase holdup of gas-liquid two-phase flow in shale gas horizontal wells can be obtained.

Key words：Shale gas horizontal well; Gas-liquid two-phase flow; Phase holdup measurement; Near-infrared absorption

收稿日期: 2024-07-10 修订日期: 2024-11-26

中图分类号:

O436

基金资助: 国家自然科学基金项目(62173290, 62306264)，中央引导地方科技发展资金项目(236Z0303G)，河北省自然科学基金项目（F2022203008, F2024203091），河北省高等学校科学技术研究项目(QN2023189)、河北省创新能力提升计划项目(22567626H)资助

通讯作者: 李贺 E-mail: lihe@ysu.edu.cn

作者简介: 孔维航，1984年生，燕山大学信息科学与工程学院副教授 e-mail: 1873544114@qq.com

引用本文:

孔维航，张恒恒，李佩宇，李洋，回耀智，李贺. 甲烷和水的水平气液两相流近红外吸收特性分析[J]. 光谱学与光谱分析, 2025, 45(06): 1551-1556.
KONG Wei-hang, ZHANG Heng-heng, LI Pei-yu, LI Yang, HUI Yao-zhi, LI He. Study on Near-Infrared Absorption Characteristics of Horizontal Gas-Liquid Two-Phase Flow of Methane and Water. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(06): 1551-1556.

链接本文:

https://www.gpxygpfx.com/CN/10.3964/j.issn.1000-0593(2025)06-1551-06 或 https://www.gpxygpfx.com/CN/Y2025/V45/I06/1551

[1] Feng D, Chen Z X, Wu K L, et al. The Canadian Journal of Chemical Engineering, 2022, 100(11): 3084.
[2] Gou L, Yang Z, Min C, et al. Applied Energy, 2024, 371: 123673.
[3] BAO Yong, DONG Feng, TAN Chao(鲍勇, 董峰, 谭超). Journal of Engineering Thermophysics(工程热物理学报), 2023, 44(6): 1583.
[4] Jeshvaghani, P A, Khorsandi M, Panahi R. Flow Measurement and Instrumentation, 2022, 86: 102190.
[5] Shi X W, Tan C, Dong F, et al. IEEE Sensors Journal, 2021, 21(11): 12913.
[6] CHEN Yang-zheng, WANG Xiao-xin, WANG Bo, et al(陈阳正, 王小鑫, 王博, 等). Instrument Technique and Sensor(仪表技术与传感器), 2020, (2): 114.
[7] FANG Li-de, LIANG Yu-jiao, LI Xiao-ting, et al(方立德, 梁玉娇, 李小亭, 等). Journal of Electronic Measurement and Instrumentation(电子测量与仪器学报), 2014, 28(5): 528.
[8] FANG Li-de, ZHANG Zhen-yu, XU Xiao-xiao, et al(方立德, 张真玉, 徐潇潇, 等). Chinese Journal of Scientific Instrument(仪器仪表学报), 2021, 42(12): 236.
[9] FANG Li-de, WANG Shao-chong, WANG Pei-pei, et al(方立德, 王少冲, 王配配, 等). Acta Metrologica Sinica (计量学报), 2019, 40(6): 1043.
[10] Mithran N, Venkatesan M. Chemical Engineering Communications, 2021, 208(6): 870.
[11] KAN Ling-ling, ZHU Fu-hai, LIANG Hong-wei(阚玲玲，朱富海，梁洪卫). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2024, 44(3): 829.
[12] LI Jun-hao, ZHENG Kai-yuan, XI Zhen-hai, et al(李俊豪, 郑凯元, 席振海, 等). Chinese Journal of Lasers(中国激光), 2021, 48(16): 1610002.
[13] WANG Qian-jin, SUN Peng-shuai, ZHANG Zhi-rong, et al(王前进, 孙鹏帅, 张志荣, 等). Chinese Journal of Lasers(中国激光), 2024, 51(8): 0811004.
[14] SONG Zhi-yi, ZENG Xiang-ying, ZHANG Biao, et al(宋之怡, 曾祥英, 张彪, 等). Natural Gas Geoscience(天然气地球科学), 2024, 35(4): 718.
[15] Tan B, He Z M, Fang Y C, et al. Science of the Total Environment，2023, 883: 163478.