稠油注空气开发技术的基础研究与应用

史琳; 许强辉

doi:10.16511/j.cnki.qhdxxb.2022.25.010

清华大学学报（自然科学版） >

2022 , Vol. 62 >Issue 4: 722 - 734

DOI: https://doi.org/10.16511/j.cnki.qhdxxb.2022.25.010

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稠油注空气开发技术的基础研究与应用

史琳 ,
许强辉

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清华大学能源与动力工程系, 北京 100084

收稿日期: 2021-09-23

网络出版日期: 2022-04-14

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Fundamental studies of air injection for heavy crude oil recovery and its applications

SHI Lin ,
XU Qianghui

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Department of Energy and Power Engineering, Tsinghua University, Beijing 100084, China

Received date: 2021-09-23

Online published: 2022-04-14

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摘要

稠油是未来重要接替能源之一,具有黏度高、储量大、开采难度高的特点。稠油注空气开发技术是我国稠油开发的重大战略接替技术,具有原位生热、高采收与绿色低碳的显著优势,但是,其地下的物理化学过程极其复杂,而相应的基础研究工作仍较薄弱。自“十二五”以来,本课题组逐渐在“稠油中低温氧化放热特征与影响因素”“稠油高温氧化燃料(焦炭)的形成和物理化学性质”“稠油氧化的拟组分反应动力学模型”“高温氧化前缘的多物理化学场耦合机制”“井组尺度下油藏中‘热流化’的耦合和传递规律”等研究方向开展了稠油注空气开发技术的基础科学问题研究和工程应用探索。建立了测量稠油氧化放热规律、产物性质与渗流参数的实验装置和方法,构建了多尺度的稠油氧化“热流化”耦合过程的数值模拟方法,这些研究成果有效推动了我国稠油注空气开发技术在基础研究和工程应用上的进步。

关键词： 稠油; 注空气开采; 中低温氧化; 高温氧化; 热流化耦合; 多尺度数值模拟

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史琳 , 许强辉 . 稠油注空气开发技术的基础研究与应用[J]. 清华大学学报（自然科学版）, 2022 , 62(4) : 722 -734 . DOI: 10.16511/j.cnki.qhdxxb.2022.25.010

Abstract

Heavy crude oil is a valuable energy resource that is very abundant but also very viscous which complicates exploitation of these resources. One efficient and environmentally friendly heavy oil recovery technique uses exothermic oxidation reactions with a small amount of the oil reacting with oxygen in the injected pressured air. However, the lack of a thorough fundamental understanding of the complex multiple physicochemical and thermal processes in the reservoir limits broad use of this technique. In the past decade, our research group has conducted fundamental research in this field, including "The basic heat release characteristics and key factors affecting moderate temperature oxidation", "coke formation and chemical properties", "reaction model for low asphaltene heavy oil", "combustion regimes for high temperature oxidation at various operating conditions", and "reservoir scale simulations of the moderate temperature oxidation technique". Experimental systems were constructed to measure the heat release, the product properties and the transport properties during the heavy oil oxidation. Multiscale numerical simulations were developed for pore-scale, lab-scale and reservoir-scale studies to understand the coupling mechanisms at different scales. These research results have improved our fundamental understanding and promoted industrial applications of this heavy oil recovery technique in China.

Key words： heavy oil; air injection recovery; low-moderate temperature oxidation; high temperature oxidation; thermal-flow-chemistry coupling; multiscale numerical simulations

参考文献

[1] SANTOS R G, LOH W, BANNWART A C, et al. An overview of heavy oil properties and its recovery and transportation methods[J]. Brazilian Journal of Chemical Engineering, 2014, 31(3):571-590.
[2] 宁奎, 袁士宝, 蒋海岩. 火烧油层理论与实践[M]. 东营:中国石油大学出版社, 2009. NING K, YUAN S B, JIANG H Y. In-situ combustion theory & practice[M]. Dongying:China University of Petroleum Press, 2009. (in Chinese)
[3] LEI T M, WANG Z, LUO K H. Study of pore-scale coke combustion in porous media using lattice Boltzmann method[J]. Combustion and Flame, 2021, 225:104-119.
[4] YANG M, HARDING T G, CHEN Z X. Numerical investigation of the mechanisms in co-injection of steam and enriched air process using combustion tube tests[J]. Fuel, 2019, 242:638-648.
[5] YUAN C D, SADIKOV K, VARFOLOMEEV M, et al. Low-temperature combustion behavior of crude oils in porous media under air flow condition for in-situ combustion (ISC) process[J]. Fuel, 2020, 259:116293.
[6] 许强辉. 稠油火驱燃烧前缘的焦炭理化特性与反应传递问题研究[D]. 北京:清华大学, 2017. XU Q H. Chemical-structural properties of the coke and reactive transport of the combustion front during crude oil in-situ combustion[D]. Beijing:Tsinghua University, 2017. (in Chinese)
[7] 刘冬. 稠油火驱过程中的成焦机理与燃烧带推进特性研究[D]. 北京:清华大学, 2021. LIU D. Research on the coking mechanisms of heavy oil and the combustion zone propagation characteristics during in-situ combustion[D]. Beijing:Tsinghua University, 2021. (in Chinese)
[8] SARATHI P S. In-situ combustion handbook——principles and practices[R]. Tulsa, OK (US):National Petroleum Technology Office, 1999.
[9] 张方礼, 户昶昊, 马宏斌, 等. 辽河油田火驱开发技术进展[J]. 特种油气藏, 2020, 27(6):12-19. ZHANG F L, HU C H, MA H B, et al. Development of fire flooding technology in Liaohe oilfield[J]. Special Oil & Gas Reservoirs, 2020, 27(6):12-19. (in Chinese)
[10] XI C F, GUAN W L, HUANG J H. Research and application of fire-flooding technologies in post-steam injected heavy oil reservoir[C]//International Petroleum Technology Conference. Beijing, China:OnePetro, 2013.
[11] ALEXANDER J D, MARTIN W L, DEW J N. Factors affecting fuel availability and composition during in situ combustion[J]. Journal of Petroleum Technology, 1962, 14(10):1154-1164.
[12] BOUSAID I S, RAMEY JR H J. Oxidation of crude oil in porous media[J]. Society of Petroleum Engineers Journal, 1968, 8(2):137-148.
[13] RANJBAR M. Influence of reservoir rock composition on crude oil pyrolysis and combustion[J]. Journal of Analytical and Applied Pyrolysis, 1993, 27(1):87-95.
[14] 江航. 稠油中温氧化生热降黏基础实验研究[D]. 北京:中国石油勘探开发研究院, 2016.JIANG H. Experimental studies of heat release and viscosity reduction characteristics during the crude oil moderate temperature oxidation[D]. Beijing:Research Insititute of Pertroleum Exploration & Development, 2016. (in Chinese)
[15] FAN C, ZAN C, ZHANG Q, et al. Air injection for enhanced oil recovery:In situ monitoring the low-temperature oxidation of oil through thermogravimetry/differential scanning calorimetry and pressure differential scanning calorimetry[J]. Industrial & Engineering Chemistry Research, 2015, 54(26):6634-6640.
[16] FAN C, ZAN C, ZHANG Q, et al. The oxidation of heavy oil:Thermogravimetric analysis and non-isothermal kinetics using the distributed activation energy model[J]. Fuel Processing Technology, 2014, 119:146-150.
[17] 韩云超. 稠油中低温氧化生热基础实验与数值模型研究[D]. 北京:清华大学, 2018. HAN Y C. Basic experimental and numerical model study of low to medium temperature oxidation heating in heavy oil[D]. Beijing:Tsinghua University, 2018. (in Chinese)
[18] YANG J Y, XU Q H, JIANG H, et al. Reaction model of low asphaltene heavy oil from ramped temperature oxidation experimental analyses and numerical simulations[J]. Energy, 2021, 219:119669.
[19] MOORE R G, LAURESHEN C J, MEHTA S A, et al. Observations and design considerations for in situ combustion projects[J]. Journal of Canadian Petroleum Technology, 1999, 38(13):1-9.
[20] YOSHIKI K S, PHILLIPS C R. Kinetics of the thermo-oxidative and thermal cracking reactions of Athabasca bitumen[J]. Fuel, 1985, 64(11):1591-1598.
[21] DRICI O, VOSSOUGHI S. Study of the surface area effect on crude oil combustion by thermal analysis techniques[J]. Journal of Petroleum Technology, 1985, 37(4):731-735.
[22] HASCAKIR B, KOVSCEK A R. Analysis of in-situ combustion performance in heterogeneous media[C]//SPE Heavy Oil Conference. Calgary, Alberta, Canada:Society of Petroleum Engineers, 2014.
[23] 关文龙, 马德胜, 梁金中, 等. 火驱储层区带特征实验研究[J]. 石油学报, 2010, 31(1):100-104, 109. GUAN W L, MA D S, LIANG J Z, et al. Experimental research on thermodynamic characteristics of in-situ combustion zones in heavy oil reservoir[J]. Acta Petrolei Sinica, 2010, 31(1):100-104, 109. (in Chinese)
[24] 唐君实, 关文龙, 蒋有伟, 等. 稀油火烧油层物理模拟[J]. 石油学报, 2015, 36(9):1135-1140. TANG J S, GUAN W L, JIANG Y W, et al. Physical simulation of light oil in-situ combustion[J]. Acta Petrolei Sinica, 2015, 36(9):1135-1140. (in Chinese)
[25] 梁金中, 关文龙, 蒋有伟, 等. 水平井火驱辅助重力泄油燃烧前缘展布与调控[J]. 石油勘探与开发, 2012, 39(6):720-727. LIANG J Z, GUAN W L, JIANG Y W, et al. Propagation and control of fire front in the combustion assisted gravity drainage process using horizontal wells[J]. Petroleum Exploration and Development, 2012, 39(6):720-727. (in Chinese)
[26] 江航, 昝成, 宋新民, 等. 高压近绝热量热法获取原油氧化动力学参数[J]. 石油学报, 2014, 35(4):745-748. JIANG H, ZAN C, SONG X M, et al. Determination of oxidation kinetics parameters for crude oil using high pressure and near adiabatic calorimetry method[J]. Acta Petrolei Sinica, 2014, 35(4):745-748. (in Chinese)
[27] 唐君实, 关文龙, 梁金中, 等. 热重分析仪求取稠油高温氧化动力学参数[J]. 石油学报, 2013, 34(4):775-779. TANG J S, GUAN W L, LIANG J Z, et al. Determination on high-temperature oxidation kinetic parameters of heavy oils with thermogravimetric analyzer[J]. Acta Petrolei Sinica, 2013, 34(4):775-779. (in Chinese)
[28] MAHINPEY N, AMBALAE A, ASGHARI K. In situ combustion in enhanced oil recovery (EOR):A review[J]. Chemical Engineering Communications, 2007, 194(8):995-1021.
[29] 谭闻濒. 多孔介质中稠油结焦特性及其渗流实验研究[D]. 北京:清华大学, 2015. TANG W P. Coking properties of heavy oil in porous media and its seepage experiment research[D]. Beijing:Tsinghua University, 2015. (in Chinese)
[30] XU Q H, JIANG H, ZAN C, et al. Coke formation and coupled effects on pore structure and permeability change during crude oil in situ combustion[J]. Energy & Fuels, 2016, 30(2):933-942.
[31] 江航, 许强辉, 马德胜, 等. 注空气开采过程中稠油结焦量影响因素[J]. 石油学报, 2016, 37(8):1030-1036. JIANG H, XU Q H, MA D S, et al. Influence factors of coking amount during recovery of heavy oil by air injection[J]. Acta Petrolei Sinica, 2016, 37(8):1030-1036. (in Chinese)
[32] 许强辉, 江航, 史琳, 等. 注空气采油过程中焦炭生成及理化性质研究的装置及方法:105445444A [P]. 2016-03-30. XU Q H, JIANG H, SHI L, et al. Experimental apparatus and method for investigating coke formation and chemical-structural properties during crude oil air injection technique:105445444A [P]. 2016-03-30. (in Chinese)
[33] XU Q H, JIANG H, MA D S, et al. Pyrolysis of a low asphaltene crude oil under idealized in situ combustion conditions[J]. Energy & Fuels, 2017, 31(10):10545-10554.
[34] XU Q H, LIU Z M, JIANG H, et al. Chemical-structural properties of the coke produced by low temperature oxidation reactions during crude oil in-situ combustion[J]. Fuel, 2017, 207:179-188.
[35] 许然. 火烧油层技术中焦炭分布三维精细表征及焦炭性质研究[D]. 北京:清华大学, 2016. XU R. Advanced characterization of three-dimensional distribution of coke in coking sand and study on properties of coke[D]. Beijing:Tsinghua University, 2015. (in Chinese)
[36] 郑若楠. 稠油在典型黏土矿物作用下的热转化成焦研究[D]. 北京:清华大学, 2020. ZHENG R N. Research on the coke formation during the thermal conversion of heavy oil under the effect of typical clay minerals[D]. Beijing:Tsinghua University, 2020. (in Chinese)
[37] CNUDDE V, BOONE M N. High-resolution X-ray computed tomography in geosciences:A review of the current technology and applications[J]. Earth-Science Reviews, 2013, 123:1-17.
[38] WILDENSCHILD D, SHEPPARD A P. X-ray imaging and analysis techniques for quantifying pore-scale structure and processes in subsurface porous medium systems[J]. Advances in Water Resources, 2013, 51:217-246.
[39] MORENO-ATANASIO R, WILLIAMS R A, JIA X D. Combining X-ray microtomography with computer simulation for analysis of granular and porous materials[J]. Particuology, 2010, 8(2):81-99.
[40] XU Q H, LONG W, JIANG H, et al. Quantification of the microstructure, effective hydraulic radius and effective transport properties changed by the coke deposition during the crude oil in-situ combustion[J]. Chemical Engineering Journal, 2018, 331:856-869.
[41] 史琳, 许然, 许强辉, 等. 基于显微CT技术的结焦砂3维孔隙结构精细表征[J]. 清华大学学报(自然科学版), 2016, 56(10):1079-1084.SHI L, XU R, XU Q H, et al. Advanced characterization of three-dimensional pores in coking sand by micro-CT[J]. Journal of Tsinghua University (Science and Technology), 2016, 56(10):1079-1084. (in Chinese)
[42] OGUNBANWO O, GERRITSEN M, KOVSCEK A R. Uncertainty analysis on in-situ combustion simulations using experimental design[C]//SPE Western Regional Meeting. Bakersfield, California, USA:Society of Petroleum Engineers, 2012.
[43] 蒋海岩, 高成国, 袁士宝, 等. 火烧油层过程中稠油氧化反应的启动机理及干预机制[R]. 西安:西安石油大学, 中国石油天然气股份有限公司新疆油田分公司, 2020. JIANG H Y, GAO C G, YUAN S B, et al. The initiation and intervention mechanism of crude oil oxidation reactions during in-situ combustion[R]. Xi'an:Xi'an Shiyou University, PetroChina Xinjiang Oilfield Company, 2020. (in Chinese)
[44] XU Q H, LONG W, JIANG H, et al. Pore-scale modelling of the coupled thermal and reactive flow at the combustion front during crude oil in-situ combustion[J]. Chemical Engineering Journal, 2018, 350:776-790.
[45] XU Q, DAI X, YANG J, et al. Pore-scale modeling of coke combustion in a multiscale porous medium using the micro-continuum framework[J]. Journal of Fluid Mechanics, 2022, 932:A51.
[46] ZHU Z Y, LIU Y N, LIU C H, et al. In-situ combustion frontal stability analysis[J]. SPE Journal, 2021, 26(4):2271-2286.
[47] SOULAINE C, ROMAN S, KOVSCEK A, et al. Mineral dissolution and wormholing from a pore-scale perspective[J]. Journal of Fluid Mechanics, 2017, 827:457-483.
[48] CINAR M, CASTANIER L M, KOVSCEK A R. Combustion kinetics of heavy oils in porous media[J]. Energy & Fuels, 2011, 25(10):4438-4451.
[49] SEQUERA B, MOORE R G, MEHTA S A, et al. Numerical simulation of in-situ combustion experiments operated under low temperature conditions[J]. Journal of Canadian Petroleum Technology, 2010, 49(1):55-64.
[50] YANG M, HARDING T G, CHEN Z X. An improved kinetics model for in situ combustion of pre-steamed oil sands[J]. Energy & Fuels, 2017, 31(4):3546-3556.
[51] JIANG H, YANG J Y, HUANG J, et al. Heat release model for the low temperature oxidation of heavy oils from experimental analyses and numerical simulations[J]. Energy & Fuels, 2019, 33(5):3970-3978.
[52] CINAR M, CASTANIER L, KOVSCEK A R. Improved analysis of the kinetics of crude-oil in-situ combustion[C]//SPE Western Regional and Pacific Section AAPG Joint Meeting. Bakersfield, California, USA:Society of Petroleum Engineers, 2008.

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