超高含水原油混合流动及初始沉积特性

doi:10.7523/j.issn.2095-6134.2020.02.012

中国科学院大学学报 ›› 2020, Vol. 37 ›› Issue (2): 228-233.DOI: 10.7523/j.issn.2095-6134.2020.02.012

超高含水原油混合流动及初始沉积特性

邢晓凯, 吕朝旭, 刘珈铨

中国石油大学(北京)油气管道输送安全国家工程实验室/城市油气输配技术北京市重点实验室, 北京 102249

收稿日期:2019-01-21 修回日期:2019-05-31 发布日期:2020-03-15
通讯作者: 邢晓凯
基金资助:
国家自然科学基金（51574259）、中国石油大学（北京）克拉玛依校区人才引进基金（YJ2018B02001）资助

Study on mixed flow and initial deposition characteristics of extra-high water-cut crude oil

XING Xiaokai, Lü Zhaoxu, LIU Jiaquan

National Engineering Laboratory for Pipeline Safety/Beijing Key Laboratory of Urban Oil and Gas Distribution Technology, China University of Petroleum(Beijing), Beijing 102249, China

Received:2019-01-21 Revised:2019-05-31 Published:2020-03-15

摘要/Abstract

摘要： 使用自行设计的实验装置，对超高含水原油的流动特性和初始沉积过程进行探究。系统研究实验温度、混合流速和体积含水率对超高含水原油初始沉积过程的影响，分析不同温度下原油的运动形态和初始沉积方式。初始沉积过程可分为蔓延沉积过程和粘连沉积过程，根据沉积特点和压降曲线的变化趋势将初始沉积过程分为3个阶段：沉积诱导期、快速沉积期和沉积动态平衡期。通过对沉积物碳数分布的分析，得知超高含水原油初始沉积过程中，同时存在剪切剥离作用、胶凝作用和分子扩散作用。实验温度和体积含水率主要通过改变胶凝作用和分子扩散来影响初始沉积过程，混合流速通过改变剪切剥离强度来影响初始沉积过程。

关键词: 超高含水原油, 混合流动, 初始沉积, 胶凝作用, 剪切剥离, 分子扩散

Abstract: An experimental flow installation is designed and constructed,and it is used to study the flow characteristics and initial deposition process of extra high water-cut crude oil. The effects of the experimental temperature, mixing velocity, and volumetric water content on the initial deposition process of extra high water-cut oil are studied systematically. According to the movement patterns of crude oil and the initial deposition modes gained at different temperatures, the initial deposition process has two types, uniform deposition process and non-uniform deposition process. According to the sedimentary characteristics and the variation trends of the pressure drop curves, the initial deposition process can be divided into three stages:induction period of deposition, period of rapid deposition, and dynamic equilibrium period of deposition. On this basis, through the analysis of the carbon number distributions of the sediments, we find that there exist shear peeling, gelation, and molecular diffusion in the initial deposition process. The experimental temperature and volumetric water content affect the initial deposition process mainly by changing the gelation and molecular diffusion, and the mixing velocity affects the initial deposition process by changing the shear peeling.

Key words: extra high water-cut crude oil, mixed flow, initial deposition, gelation, shear peeling, molecular diffusion

中图分类号:

TE82

邢晓凯, 吕朝旭, 刘珈铨. 超高含水原油混合流动及初始沉积特性[J]. 中国科学院大学学报, 2020, 37(2): 228-233.

XING Xiaokai, Lü Zhaoxu, LIU Jiaquan. Study on mixed flow and initial deposition characteristics of extra-high water-cut crude oil[J]. , 2020, 37(2): 228-233.

参考文献

[1] 赵倩. 新北油田不加热集输工艺技术研究与应用[J]. 石油规划设计, 2010, 21(5):33-35.
[2] 韩大匡. 关于高含水油田二次开发理念、对策和技术路线的探讨[J]. 石油勘探与开发, 2010(5):583-591.
[3] 方宏长,冯明生. 中国东部几个主要油田高含水期提高水驱采收率的方向[J]. 石油勘探与开发, 1999(1):60-62,6,15.
[4] 胡博仲, 李昌连, 宋承毅. 大庆高寒地区不加热集油术回顾与展望[J]. 石油规划设计, 1995(2):32-33.
[5] 曹锦艳, 杜会侠. 冬季降温集输和不加热集输可行性研究[J]. 中国西部科技, 2009, 8(7):20-21.
[6] Liu X Y, Wang D X, Han G Y, et al. Temperature limit for oil-gas-water mixed transportation in safety during oil production with special high water-cut[J]. Acta Petrolei Sinica, 2005, 26(3):102-105.
[7] Liu X Y, Liu D W, Mao Q J, et al. The flow pattern study of oil-gas-water three-phase flow in horizontal circular gathering and transferring pipeline[J]. J Eng Therm, 2010, 31(12):2038-2042.
[8] Song Y, Zhan H L, Zhao K, et al. Simultaneous characterization of water content and distribution in high-water-cut crude oil[J]. Energy & Fuels, 2016, 30(5):35-47.
[9] Sarica C, Panacharoensawad E. Review of paraffin deposition research under multiphase flow conditions[J]. Energy & Fuels, 2012, 26(7):3968-3978.
[10] Hamoud A A A, Davidsen S. An approach for simulation of paraffin deposition in pipelines as a function of flow characteristics with a reference to Teesside oil pipeline[J]. Petroleum, 1995(6):213-224.
[11] 高歌, 吴海浩, 全青, 等. 气液两相间歇流管道蜡沉积实验研究[J]. 中国科学院大学学报, 2017, 34(2):226-231.
[12] LU Y, Huang Z, Hoffmann R, et al. Counterintuitive effects of the oil flow rate on wax deposition[J]. Energy & Fuels, 2012, 26(7):4091-4097.
[13] Quan Q, Wang W, Wang P, et al. Wax deposition of water-in-crude oil emulsion in a flow-loop apparatus[J]. Petroleum Science & Technology, 2015, 33(5):520-526.
[14] Probjot S, Ramachran V, Fogler H S, et al. Morphological evolution of thick wax deposits during aging[J]. Aiche Journal, 2001, 47(1):6-18.
[15] Singh P, Fogler H S, Nagarajan N. Prediction of the wax content of the incipient wax-oil gel in a pipeline:an application of the controlled-stress rheometer[J]. Journal of Rheology, 1999, 43(6):1437-1451.
[16] Singh P, Youyen A, Fogler H S. Existence of a critical carbon number in the aging of a wax-oil gel[J]. Aiche Journal, 2001, 47(9):2111-2124.
[17] Paso K G, Fogler H S. Influence of paraffin composition on the aging of wax-oil gel deposits[J]. Aiche Journal, 2004, 49(12):3241-3252.
[18] Paso K G, Fogler H S. Bulk stabilization in wax deposition systems[J]. Energy & Fuels, 2004, 18(4):1005-1013.
[19] Quan Q, Gong J, Wang W, et al. Study on the aging and critical carbon number of wax deposition with temperature for crude oils[J]. Journal of Petroleum Science & Engineering, 2015, 130(1):1-5.
[20] Coutinho J A, Lopes D S, Aitur F, et al. Evidence for the aging of wax deposits in crude oils by Ostwald ripening[J]. Petroleum Science & Technology, 2003, 21(3/4):381-391.
[21] Hoffmann R, Amundsen L, Huang Z, et al. Wax deposition in stratified oil/water flow[J]. Energy & Fuels, 2012, 26(6):3416-3423.
[22] Jennings D W, Weispfennig K. Effects of shear and temperature on wax deposition:coldfinger investigation with a gulf of Mexico crude oil[J]. Energy & Fuels, 2005, 19(4):1376-1386.
[23] Wang P, Wang W, Gong J, et al. Effects of the dispersed phase on oil/water wax deposition[J]. ASME J Energy Resour Technol, 2013, 135(4):317-331.
[24] Anosike C F. Effect of flow patterns on oil-water flow paraffin deposition in horizontal pipes[D]. Tulsa:Tulsa University, 2006.
[25] Hunt Jr E B. Laboratory study of paraffin deposition[J]. Journal of Petroleum Technology, 1962,14(11):1259-1269.
[26] Bern P A, Withers V R, Cairns J R. Wax deposition in crude oil pipelines[C]//Proceedings of The European Offshore Petroleum Conference, London, England, 1980:21-24.
[27] 黄启玉. 含蜡原油管道蜡沉积模型的研究[D].北京:中国石油大学(北京), 2000.
[28] Visintin R G, Lapasin R. Rheological behavior and structural interrelation of waxy crude oil gels[J]. Langmuir, 2005, 21(4):6240-6249.
[29] Chang C, Boger D V, Nguyeu Q D. The yielding of waxy crude oils[J]. Industrial and Engineering Chemistry Research, 1998, 37(4):1551-1559.
[30] 吕朝旭, 邢晓凯, 柯鲁峰, 等.高含水原油流动沉积实验装置研制[J]. 石油化工高等学校学报, 2018(6):83-86.
[31] Weingarten J S, Euchner J A. Methods for predicting wax precipitation and deposition[J]. Spe Production Engineering, 1988, 3(1):121-126.
[32] Couto G H, Chen H, Delle-Case E, et al. An investigation of two-phase oil/water paraffin deposition[J]. Spe Production & Operations, 2008, 23(1):410-55.
[33] Gong J, Zhang Y, Liao L, et al. Wax deposition in the oil/gas two-phase flow for a horizontal pipe[J]. Energy & Fuels, 2011, 25(4):1624-1632.

超高含水原油混合流动及初始沉积特性

Study on mixed flow and initial deposition characteristics of extra-high water-cut crude oil

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 0

编辑推荐

Metrics

本文评价

访问统计

联系我们