Heavy oil component characterization with multi-dimensional unilateral NMR 被引量：4

Heavy oil component characterization with multi-dimensional unilateral NMR

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摘要 Heavy oil is a complicated mixture and a potential resource and has attracted much attention since the end of last century. It is important to characterize the composition of heavy oil to enhance its recovery efficiency. A designed unilateral Nuclear Magnetic Resonance （NMR） sensor with a Larmor frequency of 20 MHz and a well-defined constant gradient of 23.25 T/m was employed to acquire three- dimensional （3D） data for three heavy oil samples. The highly-constant gradient is advantageous for diffusion coefficient measurement of heavy oil. A fast data-implementation procedure including specially designed 3D pulse sequence and Inversion Laplace Transform （ILT） algorithm was adopted to process the data and extract 3D T1-D-T2 probability function. It indicates that NMR relaxometry and diffusometry are useful to characterize the components of heavy oil samples. NMR results were compared with independent measurements of fractionation and gas chromatography analysis. Heavy oil is a complicated mixture and a potential resource and has attracted much attention since the end of last century. It is important to characterize the composition of heavy oil to enhance its recovery efficiency. A designed unilateral Nuclear Magnetic Resonance （NMR） sensor with a Larmor frequency of 20 MHz and a well-defined constant gradient of 23.25 T/m was employed to acquire three- dimensional （3D） data for three heavy oil samples. The highly-constant gradient is advantageous for diffusion coefficient measurement of heavy oil. A fast data-implementation procedure including specially designed 3D pulse sequence and Inversion Laplace Transform （ILT） algorithm was adopted to process the data and extract 3D T1-D-T2 probability function. It indicates that NMR relaxometry and diffusometry are useful to characterize the components of heavy oil samples. NMR results were compared with independent measurements of fractionation and gas chromatography analysis.

作者 Liu Huabing Xiao Lizhi Guo Baoxin Zhang Zongfu Zong Fangrong Deng Feng Yu Huijun V.Anferov S.Anferova

机构地区 State Key Laboratory of Petroleum Resources and Prospecting

出处《Petroleum Science》 SCIE CAS CSCD 2013年第3期402-407,共6页 石油科学（英文版）

基金 financial supports from the National Science Foundation of China (Grant No.41074102 and 41130417) "111 Program,Supported by the Programme of Introducing Talents of Discipline to Universities"(B13010) Program for Changjiang Scholars and Innovative Research Team in University

关键词 Heavy oil multi-dimensional NMR unilateral sensor Heavy oil, multi-dimensional NMR, unilateral sensor

分类号 O482.532 [理学—固体物理] TE626.25 [石油与天然气工程—油气加工工程]

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参考文献29

1Anferova S, Anferov V, Adams M, et al. Construction of the NMR- MOUSE with short dead time. Concepts in Magnetic Resonance. 2002. 15(1): 15-22.
2Anferova S, Anferov V, Rata D G, et al. A mobile NMR Device for measurements of Porosity and Pore size Distributions of Drilled core Samples. Magnetic Resonance Engineering. 2004. 23B: 26-32.
3Ams C H, Washburn K E and Callaghan P T. Multidimensional NMR Inverse Laplace Spectroscopy in Petrophysics. Petrophysics. 2007. 48(5): 380-392.
4Bloch F. Nuclear induction. Physical Review. 1946. 70(7): 460-474.
5Bliirnich B. Essential NMR. Springer. 2005.
6Chelcea R L, Fechete R, Culea E et al. Distribution of transverse relaxation times for soft-solids measured in strongly inhomogeneous magnetic fields. Journal of Magnetic Resonance. 2009. 196:178-190.
7Cowan B. Nuclear Magnetic Resonance and Relaxation. Cambridge: Cambridge University Press. 1997.
8Dunn K J, Bergman D J and Latorraca G A. Nuclear Magnetic Resonance: Petrophysical and Logging Applications. Pergamon: Elsevier Science. 2002.
9Freed D E and Hiirlimann M D. One-and two-dimensional spin correlation of complex fluids and the relation to fluid composition. Comotes Rendus Physique. 2010.11: 181-191.
10Freed D E, Burcaw L and Song Y Q. Scaling laws for diffusion coefficients in mixtures of alkanes. Physics Review Letters. 2005. 94(6): 067602.

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1张艳丽,谢德馨,白保东,曾林锁.单边磁共振成像仪磁体系统研究(英文)[J].波谱学杂志,2006,23(3):283-292. 被引量：5
2Blumich B, Haber S, Zia W. Compact NMR[M]. Berlin: De Gruyter, 2014, 1.
3Anferova S, Anferov V, Adams M, et al. Construction of the NMR- MOUSE with short dead time[J]. Concepts Magn Reson, 2002, 15(1): 15-25.
4Blumich B, Perlo J, Casanova F. Mobile single-sided NMR[J]. Nuclear Magnetic Resonance Spectroscopy, 2008, 52:197 -269.
5Anferova S, Anferov V, Rata D G, et al. A mobile NMR device for measurements of porosity and pore size distributions of drilled core samples[J]. Concept Magn Reson B: Magn Reson Eng, 2004, 23: 26-32.
6XieJun.peng(谢俊鹏),YaoYing-ying(姚缨英)DesignofcompletelyopenMRImagnet(完全开放方式磁共振成像磁体的设计)[D].ZhejiangUniversitymaster’s degreethesis(浙江大学硕士学位论文),2006.
7Watzlaw J, Mtintjes J, Mokwa W, et aL Mobile single-sided NMR with micro structured multilayer coil arrays[C]. 53rd Experimental Nuclear Magnetic Resonance Conference, Poster 174.
8Chang W H, Chung C Y, Chert J H, et al. Simple mobile single-sided NMR apparatus with a relatively homogeneous Bo distribution[J]. MRI, 2011, 29: 869-876.
9Maxime L, Emesto D, Juan P, Blumich B. Single-sided magnetic resonance profiling in biological and materials science[J]. J Magn Reson, 2012, 215: 74-84.
10Blumich B, Casanova F, Appelt S, et al. NMR at low magnetic fields[J]. Chem Phys Lett, 2009, 477:231 -240.

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5《石油化工》最新国外摘录情况[J].石油化工,2005,34(6):572-572.
6Kanu,EP,宋福印.依靠系统分析和准确的数据实现气举最优化[J].油气田开发工程译丛,1992(12):26-29.
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Heavy oil component characterization with multi-dimensional unilateral NMR 被引量：4

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