Detection and Analysis of Water Content of Crude Oil by Near Infrared Spectroscopy
LIU Hong-ming1,2, LIU Yu-juan1*, ZHONG Zhi-cheng1, SONG Ying1*, LI Zhe1, XU Yang1
1. Key Laboratory of Geophysical Exploration Equipment, Ministry of Education, College of Instrumentation & Electrical Engineering, National Geophysical Exploration Equipment Engineering Research Center, Jilin University, Changchun 130012, China
2. Tonghua Normal University, Tonghua 134000,China
Abstract:As an important strategic resource, petroleum has an important significance in real-time analysis and detection of its components in the petrochemical industry. With the continuous development of petroleum resources, in the production process of long-term oil wells and before the exploitation of new oil wells, it is necessary to analyze and test the components of underground crude oil to determine the necessity of mining. Real-time detection of crude oil components plays a key role in the process of crude oil exploitation, production, storage, transportation and sales. In view of the low accuracy and low efficiency of traditional detection methods, near-infrared spectroscopy, which has been widely and effectively applied in the field of measurement, has been introduced into the research methods of crude oil components detection technology in recent years. In this paper, the underground crude oil was used as the research object, and the experimental samples of 39 components with crude oil ratio of 1%~20% were prepared by using the purified crude oil and water obtained from Daqing Oilfield to simulate the underground crude oil. In this paper, the basic principle of the measurement of crude oil components by near-infrared spectroscopy is studied. The near-infrared spectroscopy data measurement system of crude oil samples is integrated with the halogen source and supporting components by SW2520 near-infrared spectroscopy, and 39 groups are collected by this measurement after system standardization testing. Moving window smoothing Savitzky-Golay convolution smoothing and Savitzky-Golay convolution derivation method of near infrared spectrum data of crude oil near infrared spectral data is used to remove noise, two analysis methods of near-infrared spectra of crude sample partial least squares and support vector machine (SVM) regression method are used for retreatment modeling, crude oil component analysis prediction model is established respectively. The results show that the RMS predicted by partial least square method is 0.003 755 14, and the coefficient of determination R2 was 0.999 999. The prediction effect is very good. In this study, the near infrared spectroscopy (NIRS) technology is used to test and analyze the simulated test samples with different proportions, which provides a new idea for the detection of the components of the downhole crude oil. This method effectively solves the detection problem of the water content of the crude oil and provides technical support for the development of the real-time crude oil detection and analysis equipment in the field.
Key words:Crude oil; Near infrared spectrum; Pretreatment; Partial least squares
刘宏明,刘玉娟,仲志成,宋 莹,李 哲,徐 洋. 一种油田原油含水率的近红外光谱检测与分析方法[J]. 光谱学与光谱分析, 2021, 41(02): 505-510.
LIU Hong-ming, LIU Yu-juan, ZHONG Zhi-cheng, SONG Ying, LI Zhe, XU Yang. Detection and Analysis of Water Content of Crude Oil by Near Infrared Spectroscopy. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2021, 41(02): 505-510.
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