天然气地球科学
高级检索
作者投稿 专家审稿 编辑办公

天然气地球科学

• 天然气地质学 • 上一篇    下一篇

煤系有机质演化过程中CO2对流体黏度的影响

付德亮,周世新,李靖,李源遽,马瑜   

  1. 1.甘肃省油气资源研究重点实验室,中国科学院地质与地球物理研究所兰州油气资源研究中心,
    中国科学院油气资源研究重点实验室,甘肃  兰州 730000;
    2.中国科学院大学,北京  100049
  • 收稿日期:2014-10-15 修回日期:2015-01-27 出版日期:2015-06-10 发布日期:2015-06-10
  • 通讯作者: 周世新(1966-),男,新疆焉耆人,研究员,主要从事油气地球化学研究.E-mail:sxzhou@lzb.ac.cn.
  • 作者简介:付德亮(1988-),男,甘肃敦煌人,博士研究生,主要从事油气地球化学研究.E-mail:fudl3513@foxmail.com.
  • 基金资助:

    国家自然科学基金面上项目(编号:41072105);国家重点基础研究发展规划(“973”)项目(编号:2011CB201102);国家重大专项项目(编号:2011ZX05008-004-01)联合资助.

The Impact on Fluid Viscosity of CO2 during the Evolution of the Coal

FU De-liang,ZHOU Shi-xin,LI Jing,LI Yuan-ju,MA Yu   

  1. 1.Gansu Provincial Key Laboratory of Petroleum Resources;Key Laboratory of Petroleum Resources Research,
    Institute of Geology and Geophysics,Chinese Academy of Sciences,Lanzhou 730000,China;
    2.University of Chinese Academy of Sciences,Beijing 100049,China
  • Received:2014-10-15 Revised:2015-01-27 Online:2015-06-10 Published:2015-06-10

PDF (PC)

560

摘要:

通过压力下黄金管封闭体系热模拟实验,获取了民和盆地侏罗系煤系有机质各演化阶段的流体组成后,结合软件PVT-sim中的CS黏度计算模型对煤成烃的黏度演化进行了计算,并着重讨论了煤系有机质产生的CO2对煤成烃黏度的影响。研究表明烃类流体黏度与其相态密切相关,地质条件下液相黏度要较伴生的气相黏度高出一个数量级。随着演化程度的上升,煤成烃的气液黏度都在逐渐降低。压力为10~30MPa,温度为25~125℃条件下,Easy%RO值达到0.86%以后液相黏度小于1.0mPa·s,最低可以下降至0.13mPa·s,气相黏度在不考虑近临界态时,最大黏度不超过0.1mPa·s,最低可低至0.013mPa·s。煤系有机质演化过程中产生的CO2含量变化对煤成烃黏度的影响也十分重要,不同温压条件下,受到气液两相中CO2分配比例不同的影响,气液两相的黏度呈规律性变化。总体表现为,气相和液相的黏度均随着总组分中CO2含量的降低而降低,CO2对液态烃中短碳链组分的萃取作用是造成上述变化的根本原因,在低温情况或低演化阶段会出现黏度随着CO2减少而上升的现象。

关键词: 煤系有机质, 黏度, 热模拟, CO2

Abstract:

By the pressurized sealed gold tube pyrolysis experiments,the fluid composition of Jurassic coal from the Minhe Basin at different maturity was analyzed.Combined with the Corresponding States Method in software PVT-sim,the fluid viscosity was calculated and the impact on fluid viscosity of CO2 during the evolution of the coal was discussed.The study showed that the fluid viscosity was closely related with the fluid phase,the viscosity of the liquid phase would be an order of magnitude higher than that of the associated gas under geological conditions.With increasing maturity,viscosity of the gas and liquid phases both decreased.After the Easy%RO reaches 0.86%,at 10-30MPa and  25-125℃,the maximum value of liquid viscosity was less than 1.0 mPa·s,and the minimum value would reach 0.13 mPa·s.For the gas viscosity,it was 0.1mPa·s and 0.013mPa·s,respectively.CO2 generated from coal has important influence on the petroleum viscosity.Under different temperature and pressure conditions,the distribution ration of the CO2 in gas-liquid phases affects the viscosity directly.Overall,the viscosity of both liquid and gas phases decreases with the decrease of CO2 content in total component,which is because CO2 could extract short carbon chain component in the liquid hydrocarbon Viscosity increases with the decrease of CO2 only when it is at low temperature or with low maturity.

Key words: Coal, Viscosity, Pyrolysis experiments, CO2

中图分类号: 

  • TE122.3

[1]Pedersen K S,Christensen P L.Fluids in hydrocarbon basins[J].Reviews in Mineralogy and Geochemistry,2007,65(1):241-258.
[2]Martín-Alfonso M,Martínez-Boza F,Navarro F,et al.Pressure-temperature-viscosity relationship for heavy petroleum fractions[J].Fuel,2007,86(1/2):227-233.
[3]Al-Marhoun M A,Nizamuddin S,Raheem Ali A A,et al.Prediction of crude oil viscosity curve using artificial intelligence techniques[J].Journal of Petroleum Science and Engineering,2012,86/87:111-117.
[4]Guo Xuqiang,Run Shuxia,Yang Jitao,et al.The viscosity model based on PR equation of state[J].Acta Petrolei Sinica,1999,20(3):56-61.[郭绪强,荣淑霞,杨继涛,等,基于 PR 状态方程的黏度模型[J].石油学报,1999,20(3):56-61.]
[5]Su Jihong,Yi Bin.An empirical method for determining the formation oil viscosity[J].Petroleum Exploration and Development,1999,26(5):53-5.[苏继红,易斌.确定地层原油黏度的经验方法[J].石油勘探与开发,1999,26(5):53-55.]
[6]Carr N L,Kobayashi R,Burrows D B.Viscosity of hydrocarbon gases under pressure[J].Journal of Petroleum Technology,1954,6(10):47-55.
[7]Liu Guangdi.Petroleum Geology[M].Beijing:Petroleum Industry Press,2009.[柳广弟.石油地质学[M].北京:石油工业出版社,2009.]
[8]Guo Xuqiang,Yan Wei,Rong Shuxia,et al.Eaperimental and modeling studies on viscosity of reservoir fluids-CO2 system[J].Journal of University of Petroleum:Edition of Social Sciences,China,2001,25(3):16-18.[郭绪强,阎炜,荣淑霞,等.油气藏流体—CO2体系黏度的实验测定与计算[J].石油大学学报:自然科学版,2001,25(3):16-18.]
[9]Simon R,Graue D.Generalized correlations for predicting solubility swelling and viscosity behavior of CO2-crude oil systems[J].Journal of Petroleum Technology,1965,17(1):102-106.
[10]Guo Ping,Sun Liangtian,Li Shilun,et al.Theoretical simulation and experimental study of theinfluence of CO2 injection on PVT of crude oil[J].Natural Gas Industry,2000,20(2):76-79.[郭平,孙良田,李士伦,等.CO2 注入对原油高压物性影响的理论模拟和实验研究[J].天然气工业,2000,20(2):76-79.]
[11]Pan Yi,Sun Lei,Li Shilun,et al.The method solving condensate block and mproving productivity of gas condensate reservoir[J].Joumal of Southwest Petroleum University,2007,29(2):37-40.[潘毅,孙雷,李士伦,等.凝析气藏解除反凝析污染,提高气井产能方法[J].西南石油大学学报,2007,29(2):37-40.]
[12]Holm L,Josendal V.Mechanisms of oil displacement by carbon dioxide[J].Journal of petroleum Technology,1974,26(12):1427-1438.
[13]Bicher L B,Katz D L.Viscosities of the Methane-Propane System[J].Industrial & Engineering Chemistry,1943,35(7):754-761.
[14]Lohrenz J,Bray B G,Clark C R.Calculating viscosities of reservoir fluids from their compositions[J].Journal of Petroleum Technology,1964,16(10):1171-1176.
[15]Pedersen K S,Fredenslund A,Christensen P L,et al.Viscosity of crude oils[J].Chemical Engineering Science,1984,39(6):1011-1016.
[16]Pedersen K S,Fredenslund A.An improved corresponding states model for the prediction of oil and gas viscosities and thermal conductivities[J].Chemical Engineering Science,1987,42(1):182-186.
[17]Lindeloff N,Pedersen K S,R?nningsen H P,et al.The corresponding states viscosity model applied to heavy oil systems[J].Journal of Canadian Petroleum Technology,2004,43(9):47-53.
[18]Elsharkawy A M,Alikhan A A.Models for predicting the viscosity of Middle East crude oils[J].Fuel,1999,78(8):891-903.
[19]Jarrahian A,Heidaryan E.A simple correlation to estimate natural gas viscosity[J].Journal of Natural Gas Science and Engineering,2014,20:50-57.
[20]Naseri A,nikazar M,Mousavi Dehghani S A.A correlation approach for prediction of crude oil viscosities[J].Journal of Petroleum Science and Engineering,2005,47(3/4):163-174.
[21]Riazi M R,Al-Otaibi G N.Estimation of viscosity of liquid hydrocarbon systems[J].Fuel,2001,80(1):27-32.
[22]Tang Y,Jenden P,Nigrini A,et al.Modeling early methane generation in coal[J].Energy & Fuels,1996,10(3):659-671.
[23]Behar F,Vandenbroucke M,Teermann S,et al.Experimental simulation of gas generation from coals and a marine kerogen[J].Chemical Geology,1995,126(3):247-260.
[24]Liu Jinzhong,Tang Yongchun.One example of predicting methane generation yield by hydrocarbon generating kinetics[J].Chinese Science Bulletin,1998,43(11):1187-1191.[刘金钟,唐永春.用干酪根生烃动力学方法预测甲烷生成量之一例[J].科学通报,1998,43(11):1187-1191.]
[25]Chen Jianping,Zhao Wenzhi,Wang Zhaoming,et al.The upper limit of maturity degree and poteneial of natural gas generation from marin kerogen:Tarim Basin as a studying example[J].Chinese Science Bulletin,2007,52(supplementⅠ):95-100.[陈建平,赵文智,王招明,等.海相干酪根天然气生成成熟度上限与生气潜力极限探讨——以塔里木盆地研究为例[J].科学通报,2007,52(增Ⅰ):95-100.]
[26]Li Yanjun,Chen Yicai,Zhang Yanyun,et al.Source rocks heat-press simulation expriment and its influence with pressure in the member 3 of the Shahejie Formation,middle-north area of Huanghua Depression[J].Petroleum Geology & Experiment,2005,27(4):419-424.[李延钧,陈义才,张艳云,等.黄骅坳陷中北区沙三段烃源岩热压模拟实验及其压力的影响[J].石油实验地质,2005,27(4):419-424.]
[27]Shuai Yanhua,Zhang Shuichang,Chen Jianping,et al.Methods of evaluating the gas potential of marine mature kerogen[J].Acta Geologica Sinica,2008,82(8):1129-1134.[帅燕华,张水昌,陈建平,等.海相成熟干酪根生气潜力评价方法研究[J].地质学报,2008,82(8):1129-1134.]
[28]Pedersen K S,Blilie A L,Meisingset K K.PVT calculations on petroleum reservoir fluids using measured and estimated compositional data for the plus fraction[J].Industrial & Engineering Chemistry Research,1992,31(5):1378-1384.
[29]Behar F,Vandenbroucke M,Tang Y,et al.Thermal cracking of kerogen in open and closed systems:Determination of kinetic parameters and stoichiometric coefficients for oil and gas generation[J].Organic Geochemistry,1997,26(5):321-339.
[30]Hunt J M,Lewan M,Hennet R J C.Modeling oil generation with time-temperature index graphs based on the Arrhenius Equation(1)[J].AAPG Bulletin,1991,75(4):795-807.
[31]Sweeney J J,Burnham A K.Evaluation of a simple model of vitrinite reflectance based on chemical kinetics[J].AAPG Bulletin,1990,74(10):1559-1570.
[32]Di Primio R,Horsfield B.From petroleum-type organofacies to hydrocarbon phase prediction[J].AAPG Bulletin,2006,90(7):1031-1058.
[33]Di Primio R,Dieckmann V,Mills N.PVT and phase behaviour analysis in petroleum exploration[J].Organic Geochemistry,1998,29(1):207-222.
[34]Zhang Haikun,Zhou Shixin,Fu Deliang,et al.Petroleum phase state prediction in deep reservoir of Tashen-1 well in Tarim Basin[J].Natural Gas Geoscience,2013,24(5):999-1004,1068.[张海坤,周世新,付德亮,等.塔里木盆地塔深 1 井深层油气相态预测[J].天然气地球科学,2013,24(5):999-1004,1068.]
[35]Shuai Y,Zhang S,Peng P,et al.Occurrence of heavy carbon dioxide of organic origin:Evidence from confined dry pyrolysis of coal[J].Chemical Geology,2013,358:54-60.
[36]Dai Jinxing.Characteristics of polycyclic aromatic hydrocarbon associations in some marine source rocks[J].Petroleum Exploration and Development,1997,24(2):10-14.[戴金星.中国气藏(田) 的若干特征[J].石油勘探与开发,1997,24(2):10-14.]
[37]Killops S D,Allis R G,Funnell R H.Carbon dioxide generation from coals in Taranaki Basin,New Zealand:Implications for petroleum migration in southeast Asian Tertiary basins[J].AAPG Bulletin,1996,80(4):545-568.
[38]Ennis-King J,Paterson L.Coupling of geochemical reactions and convective mixing in the long-term geological storage of carbon dioxide[J].International Journal of Greenhouse Gas Control,2007,1(1):86-93.
[39]Shuai Yanhua,Zhang Shuichang,Gao Yang,et al.Effect and quantitative evaluation of CO2 derived from organic matter in coal on the formation of tight sandstone reservoirs[J].Science China:Earth Sciences,2013,56(5):756-762.[帅燕华,张水昌,高阳,等.煤系有机质生气行为对储层致密化的可能影响及定量化评价[J].中国科学:地球科学,2013,47(7):1149-1155.]
[40]Geng Hongzhang,Chen Jianwen,Sun Renyuan,et al.Effect of dissolved carbon dioxide on the viscosity of crude oil[J].Journal of the University of Petroleum:Edition of Social Sciences,2004,28(4):78-80.[耿宏章,陈建文,孙仁远,等.二氧化碳溶解气对原油黏度的影响[J].石油大学学报:自然科学版,2004,28(4):78-80.]
[41]Zhu Yangming,Su Aiguo,Liang Digang,et al.Evaporative fractionation of oil and gas reservoir in Nanbaxian area of northern Qaidam Basin[J].Acta Petrolei Sinica,2003,24(4):31-35.[朱扬明,苏爱国,梁狄刚,等.柴达木盆地北缘南八仙油气藏的蒸发分馏作用[J].石油学报,2003,24(4):31-35.]
[42]Bo Qiwei.Determination and prediction of the bubble point pressure for CO2-oil system[J].Petroleum Drilling Techniques,2010,38(3):98-100.[薄启炜.CO2-原油体系饱和压力的测定与预测[J].石油钻探技术,2010,38(3):98-100.]
[43]Pepper A S,Corvi P J.Simple kinetic models of petroleum formation.Part I:oil and gas generation from kerogen[J].Marine and Petroleum Geology,1995,12(3):291-319.
[44]Pedersen K,Milter J.Phase Equilibrium between Gas Condensate and Brine at HT/HP Conditions[R].SPE Annual Technical Conference and Exhibition,26-29 September,Houston,Texas.SPE 90309.2004.
[45]Alquraishi A A,Shokir E M.Artificial neural networks modeling for hydrocarbon gas viscosity and density estimation[J].Journal of King Saud University-Engineering Sciences,2011,23(2):123-129.
[46]Petersen H I.The petroleum generation potential and effective oil window of humic coals related to coal composition and age[J].International Journal of Coal Geology,2006,67(4):221-248.
[47]Killops S D,Woolhouse A D,Weston R J,et al.A geochemical appraisal of oil generation in the Taranaki Basin,New Zealand[J].AAPG Bulletin,1994,78(10):1560-1585.
[48]Mckirdy D M,Chivas A R.Nonbiodegraded aromatic condensate associated with volcanic supercritical carbon dioxide,Otway Basin:Implications for primary migration from terrestrial organic matter[J].Organic Geochemistry,1992,18(5):611-627.
[1] 彭威龙,胡国艺,刘全有,贾楠,房忱琛,龚德瑜,于聪,吕玥,王鹏威,冯子齐. 热模拟实验研究现状及值得关注的几个问题[J]. 天然气地球科学, 2018, 29(9): 1252-1263.
[2] 陈斐然,张义杰,朱光有,张宝收,卢玉红,张志遥. 塔里木盆地台盆区深层天然气地球化学特征及成藏演化[J]. 天然气地球科学, 2018, 29(6): 880-891.
[3] 陈晓艳,田福清,邹华耀,郭柳汐,芦晓伟,殷杰,王道军. 湖相烃源岩热演化生烃研究——基于冀中坳陷烃源岩加水热模拟实验[J]. 天然气地球科学, 2018, 29(1): 103-113.
[4] 郭肖,王彭. 含水对普光酸性气田流体物性的影响[J]. 天然气地球科学, 2017, 28(7): 1054-1058.
[5] 王晖,张磊,石军太,张丽霞,高潮,张亮,郭超. 鄂尔多斯盆地东南部山西组泥页岩生烃热模拟实验[J]. 天然气地球科学, 2017, 28(7): 1078-1084.
[6] 郝永卯,韦馨林,董承顺. 不同驱油方式CO2微观分布特征及埋存量研究[J]. 天然气地球科学, 2017, 28(6): 846-851.
[7] 何胜林,张海荣,杨冬,吴一雄,吴进波. 高温高压条件下不同气体组分储层岩电实验及应用[J]. 天然气地球科学, 2017, 28(4): 575-581.
[8] 姜凤光,王小林,陈志海. 二氧化碳侵入前油气藏流体性质定量分析[J]. 天然气地球科学, 2017, 28(3): 488-493.
[9] 赵军,杨阳. 含CO2气层孔隙度计算方法[J]. 天然气地球科学, 2016, 27(4): 571-576.
[10] 王亮,曹海虹. 一种可能的页岩有机孔隙演化机理——以下扬子大隆组页岩为例[J]. 天然气地球科学, 2016, 27(3): 520-523.
[11] 申峰,张锋三,吴金桥,张军涛,郭庆,孙晓. CO2泡沫压裂液流变特性研究及应用[J]. 天然气地球科学, 2016, 27(3): 566-570.
[12] 何胜林,张海荣,杨冬,吴一雄. 南海西部盆地高温超压储层CO2气层测井评价技术[J]. 天然气地球科学, 2016, 27(12): 2200-2206.
[13] 朱阳升,宋学行,郭印同,徐峰,孙楠楠,魏伟. 四川盆地龙马溪组页岩的CH4和CO2气体高压吸附特征及控制因素[J]. 天然气地球科学, 2016, 27(10): 1942-1952.
[14] 王宁,李荣西,王香增,张丽霞,赵帮胜,覃小丽,李佳佳,程敬华. 海陆过渡相页岩气形成热模拟实验研究[J]. 天然气地球科学, 2016, 27(1): 189-197.
[15] 李腾飞,田辉,陈吉,程礼军. 低压气体吸附法在页岩孔径表征中的应用——以渝东南地区页岩样品为例[J]. 天然气地球科学, 2015, 26(9): 1719-1728.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!