碳酸盐岩储集层岩石物性变化与结构变形实验

SALIMIDELSHAD Yaser; MORADZADEH Ali; KAZEMZADEH Ezatallah; POURAFSHARY Peyman; MAJDI Abbas

doi:10.11698/PED.2019.03.12

石油勘探与开发 >

2019 , Vol. 46 >Issue 3: 542 - 551

DOI: https://doi.org/10.11698/PED.2019.03.12

油气勘探

碳酸盐岩储集层岩石物性变化与结构变形实验

SALIMIDELSHAD Yaser ,
MORADZADEH Ali ,
KAZEMZADEH Ezatallah ,
POURAFSHARY Peyman ,
MAJDI Abbas

展开

1. School of Mining Engineering, College of Engineering, University of Tehran, Tehran 1417614418, Iran;
2. Faculty of Research and Development in Upstream Petroleum Industry, Research Institute of Petroleum Industry, Tehran 1417614418, Iran;
3. Department of Petroleum Engineering, School of Mining and Geosciences, Nazarbayev University, Astana 010000, Kazakhstan

SALIMIDELSHAD Yaser（1984-）,男,伊朗人,现为伊朗德黑兰大学工程学院采矿工程系在读博士研究生,主要从事能源矿产勘探方面研究。地址：School of Mining Engineering, College of Engineering, University of Tehran, 16th Azar Street, Enghelab Sq., Tehran, Iran,邮政编码：1417614418。E-mail: salimidelshad@ut.ac.ir

收稿日期: 2018-09-14

修回日期: 2018-12-28

网络出版日期: 2019-05-25

收起

Experimental investigation of changes in petrophysical properties and structural deformation of carbonate reservoirs

SALIMIDELSHAD Yaser ,
MORADZADEH Ali ,
KAZEMZADEH Ezatallah ,
POURAFSHARY Peyman ,
MAJDI Abbas

Expand

1. School of Mining Engineering, College of Engineering, University of Tehran, Tehran 1417614418, Iran;
2. Faculty of Research and Development in Upstream Petroleum Industry, Research Institute of Petroleum Industry, Tehran 1417614418, Iran;
3. Department of Petroleum Engineering, School of Mining and Geosciences, Nazarbayev University, Astana 010000, Kazakhstan

Received date: 2018-09-14

Revised date: 2018-12-28

Online published: 2019-05-25

Fold

摘要

为研究压力对碳酸盐岩孔隙结构、岩石物理性质等方面的影响,在压力循环加载条件下对伊朗西南部South-Pars气田下三叠统Kangan组2个碳酸盐岩柱状岩心样品进行孔隙度、渗透率、CT扫描、扫描电子显微镜（SEM）、弹性波速度等分析。在2个岩心样品中,一个样品为方解石,另一个为含硬石膏结核的白云石,分别以6个阶段循环施加13.79 MPa和27.58 MPa的负载压力,统计分析2个样品在不同压力加载/卸载阶段下的物性变化特点。结果表明,方解石样品的孔隙度和渗透率随压力载荷的增加而减小,这与纵波和横波速度测试的结果一致。在白云石样品中则没有观察到这种趋势。在纵波和横波速度分析中可观察到压力加载阶段速度发生起伏,这可能是由于孔隙具有不同几何形状和样品中的孔隙发生变化所致。研究碳酸盐岩物性随压力的变化有助于优化调整油气藏开发方案。图13表2参48

关键词： 压力循环加载; 岩石物性; 碳酸盐岩储集层; CT扫描; 岩石物性; South-Pars气田; 下三叠统Kangan组; 结构变形

本文引用格式

SALIMIDELSHAD Yaser , MORADZADEH Ali , KAZEMZADEH Ezatallah , POURAFSHARY Peyman , MAJDI Abbas . 碳酸盐岩储集层岩石物性变化与结构变形实验[J]. 石油勘探与开发, 2019 , 46(3) : 542 -551 . DOI: 10.11698/PED.2019.03.12

Abstract

To examine the effect of pressure on pore structure and petrophysical properties of carbonate rock, the porosity, permeability, CT scanning, SEM and elastic wave velocity of two carbonate core plug samples from the Lower Triassic Kangan Formation in southwest Iranian South-Pars field were analyzed under cyclic pressure. One of the plugs was calcite and the other was dolomite with anhydrite nodules. The cyclic pressure exerted on the samples increased from 13.79 MPa to 27.58 MPa in six steps, and the variations in petrophysical properties of the two samples at different pressure loading and unloading steps were counted and analyzed. The results show that the calcite sample decreases in porosity and permeability with the increase of pressure, which is consistent with the results from compression and shear wave velocity tests. In the dolomite sample, the decreasing trend was not observed; fluctuations of compressive and shear velocities were observed during the loading stage, which may be due to different geometries of the pores and the porosity variation in the sample. Understanding the variation of carbonate petrophysical properties with pressure is helpful for optimizing reservoir development scheme.

Key words： cyclic pressure loading; petrophysical property; carbonate reservoir; CT scan; rock physical property; South-Pars field; Lower Triassic Kangan Formation; structure deformation

参考文献

[1] ADDIS M A, CHOI X, GUNNING J.The influence of the reservoir stress-depletion response on the lifetime considerations of well completion design[R]. SPE 47289, 1998.
[2] SMART B G, SOMERVILLE J M, JIN M, et al.Reservoir characterization for the management of stress-sensitivity[J]. Geological Society, London, Special Publications, 2003, 209: 145-153.
[3] KARACAN C O, GRADER A S, HALLECK P M.4-D mapping of porosity and investigation of permeability changes in deforming porous medium[R]. SPE 72379, 2001.
[4] MA F, HE S, ZHU H, et al.The effect of stress and pore pressure on formation permeability of ultra-low-permeability reservoir[J]. Petroleum Science and Technology, 2012, 30(12): 1221-1231.
[5] HAMID O, OSMAN H, RAHIM Z, et al.Stress dependent permeability of carbonate rock[R]. SPE 181589, 2016.
[6] WANG C, WU Y S, XIONG Y, et al. Geomechanics coupling simulation of fracture closure and its influence on gas production in shale gas reservoirs[R]. SPE 173222, 2015.
[7] ELHAJ M A, BARRI A, HASHAN M, et al. State of the art on porosity and permeability hysteresis: Useful techniques for hydrocarbon recovery[R]. SPE 192409, 2018.
[8] WONG T F, DAVID C, ZHU W.The transition from brittle faulting to cataclastic flow in porous sandstones: Mechanical deformation[J]. Journal of Geophysical Research: Solid Earth, 1997, 102(B2): 3009-3025.
[9] ZHENG J, ZHENG L, LIU H H, et al.Relationships between permeability, porosity and effective stress for low-permeability sedimentary rock[J]. International Journal of Rock Mechanics and Mining Sciences, 2015, 78: 304-318.
[10] TEKLU T W, LI X, ZHOU Z, ABASS H. Experimental investigation on permeability and porosity hysteresis of tight formations[R]. SPE 180226, 2018.
[11] OLIVEIRA G, CEIA M, MISSAGIA R, et al.Permeability dependence of porosity and p-wave velocity in carbonate rocks[R]. Tulsa: SEG, 2016.
[12] SHABANINEJAD M, HAGHIGHI B.Rock typing and generalization of permeability-porosity relationship for Iranian carbonate gas reservoir[R]. SPE 150819, 2011.
[13] YALALOVA V, ZHUKOV A, VOLNOV I, et al. Impact of pore structure on reservoir quality of carbonates[R]. SPE 187893, 2017.
[14] FJÆR E, HOLT RM, HORSRUD P, et al. Petroleum related rock mechanics[M]. Amsterdam: Elsevier, 2008.
[15] CIVAN F.Effect of stress shock and pressurization/depressurization hysteresis on petrophysical properties of naturally-fractured reservoir formations[R]. SPE 190081, 2018.
[16] TEKLU T W, ZHOU Z, LI X, et al.Cyclic permeability and porosity hysteresis in mudrocks: Experimental study[R]. Houston: American Rock Mechanics Association, 2016.
[17] JASTI J K, JESION G, FELDKAMP L. Microscopic imaging of porous media with X-Ray computer tomography[R]. SPE 20495, 1993.
[18] ØREN P E, BAKKE S.Reconstruction of berea sandstone and pore-scale modeling of wettability effects[J]. Journal of Petroleum Science and Engineering, 2003, 39(3/4): 177-199.
[19] RAHIMOV K, ALSUMAITI A M, JOUINI M S.Quantitative analysis of absolute permeability and porosity in carbonate rocks using digital rock physics[R]. Tokyo: 22nd Formation Evaluation Symposium of Japan, 2016.
[20] VINEGAR H J, WELLINGTON S L.Tomographic imaging of three-phase flow experiments[J]. Review of Scientific Instruments, 1987, 58(1): 96-107.
[21] HUNT P K, ENGLER P, BAJSAROWICZ C.Computed tomography as a core analysis tool: Applications, instrument evaluation, and image improvement techniques[R]. SPE 16952, 1988.
[22] LI B, TAN X, WANG F, et al.Fracture and vug characterization and carbonate rock type automatic classification using X-ray CT images[J]. Journal of Petroleum Science and Engineering, 2017, 153: 88-96.
[23] WITHJACK E M. Computed tomography for rock-property determination and fluid-flow visualization[R]. SPE 16951, 1988.
[24] WITHJACK E M, DEVIER C, MICHAEL G. The role of X-ray computed tomography in core analysis[R]. SPE 83467, 2003.
[25] WEGER R J, EBERLI G P, BAECHLE G T, et al.Quantification of pore structure and its effect on sonic velocity and permeability in carbonates[J]. AAPG Bulletin, 2009, 93: 1297-1317.
[26] ABDELKARIM A, ABDULLATIF O.Combining petrophysical properties and ultrasonic velocity for improved prediction of tight carbonate reservoir[R]. Utah: Unconventional Resources Technology Conference, 2017.
[27] SKINNER J T, TOVAR F D, SCHECHTER D S. Computed tomography for petrophysical characterization of highly heterogeneous reservoir rock[R]. SPE 177257, 2015.
[28] ADEBAYO A R, KANDIL M E, OKASHA T M, et al.Measurements of electrical resistivity, NMR pore size and distribution, and x-ray CT-scan for performance evaluation of CO₂ injection in carbonate rocks: A pilot study[J]. International Journal of Greenhouse Gas Control, 2017, 63: 1-11.
[29] AKIN S, KOVSCEK A R.Computed tomography in petroleum engineering research[J]. Geological Society, London, Special Publications, 2003, 215: 23-38.
[30] KANTZAS A.Investigation of physical properties of porous rocks and fluid flow phenomena in porous media using computer assisted tomography[J]. Situ, 1990, 14(1): 77-132.
[31] RASSENFOSS S.Need a faster measure of relative permeability? Take a CT scan and follow with digital rock analysis[J]. SPE Journal, 2017, 69(8): 28-31.
[32] SIDDIQUI S, KHAMEES A A.Dual-energy CT-scanning applications in rock characterization[R]. SPE 90520, 2004.
[33] PETUNIN V V, YIN X, TUTUNCU A N. Porosity and permeability changes in sandstones and carbonates under stress and their correlation to rock texture[R]. SPE 147401, 2011.
[34] PETUNIN V V, TUTUNCU A N, PRASAD M, et al.An experimental study for investigating the stress dependence of permeability in sandstones and carbonates[R]. Houston: 45th US Rock Mechanics/ Geomechanics Symposium, 2011.
[35] JONES S C.Two-point determinations of permeability and PV vs. net confining stress[J]. SPE Formation Evaluation, 1988, 3(1): 235-241.
[36] MCPHEE C, REED J, ZUBIZARRETA I.Core analysis: A best practice guide[J]. Elsevier, 2015, 64: 101-110.
[37] EBERLI G P, BAECHLE G T, ANSELMETTI F S, et al.Factors controlling elastic properties in carbonate sediments and rocks[J]. The Leading Edge, 2003, 22: 654-660.
[38] BRIGAUD B, VINCENT B, DURLET C, et al.Acoustic properties of ancient shallow-marine carbonates: Effects of depositional environment and digenetic processes(Middle Jurassic, Paris Basin, France)[J]. Journal of Sedimentary Research, 2010, 80: 791-807.
[39] WANG Z.Seismic properties of carbonate rocks[J]. Geophysical Development Series, 1997, 6: 29-52.
[40] BAUD P, VINCIGUERRA S, DAVID C, et al.Compaction and failure in high porosity carbonates: Mechanical data and microstructural observations[J]. Pure and Applied Geophysics, 2009, 166(5/6/7): 869-898.
[41] MAIN I, KWON O, NGWENYA BT, et al.Fault sealing during deformation-band growth in porous sandstone[J]. Geology, 2000, 28: 1131-1134.
[42] CASTAGNA J P, BATZLE M L, EASTWOOD R L.Relationships between compressional-wave and shear-wave velocities in clastic silicate rocks[J]. Geophysics, 1985, 50(4): 571-581.
[43] SUN S, JI S, WANG Q, et al.Seismic velocities and anisotropy of core samples from the Chinese continental scientific drilling borehole in the Sulu UHP terrane, eastern China[J]. Journal of Geophysical Research: Solid Earth, 2012, 117: B01206-B01230.
[44] HE T W.P- and S-wave velocity measurement and pressure sensitivity analysis of AVA response[R]. Alberta, Canada: CSPG- CSEG-CWLS Convention, 2006.
[45] KING M S.Wave velocities in rocks as a function of changes in overburden pressure and pore fluid saturates[J]. Geophysics, 1966, 31(1): 50-73.
[46] GARDNER G H F, GARDNER L W, GREGORY A R. Formation velocity and density, the diagnostic basics for stratigraphic traps[J]. Geophysics, 1974, 39(6): 770-780.
[47] FORTIN J, SCHUBNEL A, GUÉGUEN Y. Elastic wave velocities and permeability evolution during compaction of Bleurswiller sandstone[J]. International Journal of Rock Mechanics and Mining Sciences, 2005, 42(7/8): 873-889.
[48] ZHANG J, WONG T F, DAVIS D M.Micromechanics of pressure- induced grain crushing in porous rocks[J]. Journal of Geophysical Research: Solid Earth, 1990, 95(B1): 341-352.

Options

文章导航

模态框（Modal）标题

摘要

本文引用格式

Abstract

参考文献