The development of low-porosity and low-permeability oil and gas fields has been concerned by scholars all over the world. This study focuses on the sensitivity study of Chang 6 reservoir in CD block of Ordos Basin. Through analysis by such technological means as rock core fluid flow experiment, X diffraction, rock core slices, scanning electron microscopy, it is proven that Chang 6 reservoir mainly gives primary to acid sensitivity, the velocity sensitivity is in the next place and the alkaline sensitivity and water sensitivity are in the end. The sensitivity minerals mainly cover the chlorite, calcite, ferrocalcite, dolomite, siderite and other minerals. Through discussion about the relationship among porosity, permeability and sensitivity indexes, it is deemed that he relationship among porosity, permeability and sensitivity indexes is closely related, and it is found through discussion for four kinds of sensitivity indexes that the trends of velocity sensitivity and acid sensitivity index curves are consistent, and the trends of alkali sensitivity and water sensitivity index curves are consistent. The consistency on relationship possibly enables that relationship between alkali sensitivity and water sensitivity are closely related to the fluid mineralization and the velocity sensitivity and acid sensitivity are closely related to the reaction rate of fluid.

Ordos basin; Chang 6 reservoir; Sensitivity mechanism; Reservoir protection; Sensitivity indexes

Bennion, D. B., Thomas, F. B., & Bietz, R. F. (1996). Low permeability gas reservoirs: Problems, opportunities and solution for drilling, completions stimulation and production. SPE 35577. doi: 10.2118/35577-MS.

Bishop, S. R. (1997). The experimental investigation of formation damage due to the induced flocculation of clays within a sandstone pore structure by a high salinity brine. Society of Petroleum Engineers. doi: https://doi.org/10.2118/38156-MS.

Civan, F. (2007). Formation damage mechanisms and their phenomenological modeling-An overview. Society of Petroleum Engineers, 1-12. doi: https://doi.org/10.2118/107857-MS

Cong, B. H. (2011). Study on reservoir characteristic of Ordovician system Mawu section in Eastern Area of Sulige. Chengdu Univerisity of Technology.

Deng, J., Li, Y. J., Liang, L. P., & Zha, L. (2011). Sensitivity characteristics for Chang 2 reservoir in Dingbian Zhanghan area of Ordos Basin. Petroleum Geology and Engineering, 259(2), 64-66.

Du, H. D. (2012). Application study on 3D geological modeling technology in oil field recovery ratio. Shaanxi, Xi’an Shi You University.

Feng, J. P. (2008). Study on sedimentary facies and microscopic reservoir characteristics in Yanchang Formation, Northern Area, Yaodian Oilfield in Northern Shaanxi (Doctorial dessertation). Shaanxi, Northwest University.

Gale, J. F. W., Reed, R. M., & Holder, J. (2007). Natural fractures in the Barnett Shale and their importance for hydraulic fracture treatments. AAPG Bulletin, 91(4), 603-622.

Hassan, B., Rcza, R. M., Nazhat, D., & Ostojic, J. (2011). Evaluation of damage mechanisms and skin factor in tight gas reservoirs. Society of Petroleum Engineers, 1(2), 1-13. doi: https://doi.org/10.2118/142284-MS

Hatcher, G. B., & Chen, H. (1996). Evaluating formation damage risks in a Glauconitic sandstone reservoir: A case history from the offshore North West shelf of Australia. Society of Petroleum Engineers. doi: https://doi.org/10.2118/37014-MS.

Jiang, T., & Xie, X. N. (2005). Influence factors for physical property of reservoir under high temperature and overpressure in Yinggehai Basin. Geoscience-Journal of China University of Geosciences, 30(2), 215-220.

Kang, Y. L., & Luo, P. Y. (2000). Effects on minerals on sandstone reservoir damage by sticky minerals -retrospect and prospect. Drilling fluid and Completion Fluid, 17(5), 36-50.

Karacan, O., & Okandan, E. (2000). Assessment of energetic heterogeneity of coals for gas adsorption and its effect on mixture predictions for coalbed methane studies. Fuel, 79, 1963-1974.

Keim, A., Luxbacher , D., & Karmis, M. (2011). A numerical study on optimization of multilateral horizontal wellbore patterns for coalbed methane production in southern Shanxi province, China. Int. J. Coal Geol, 86, 306-317.

Kumar, H., Elsworth, D., Liu, J.S., Pone, D., & Mathews, J. P. (2012). Optimizing enhanced coalbed methane recovery for unhindered production and CO2 injectivity. Int. J. Greenh. Gas. Control, 11, 86-97 .

Li, H. Z. (2014). Study on the fine evaluation of low permeability reservoir in Yanchang Formation, Zichang County, Ordos Basin. Northwestern University,

Li, Q., Guo, J. H., Guo, Y. C., & Su, D. H., (2009). Sensitivity and forming mechanism of low-permeability sandstone reservoir in 152 area of Huachi Oilfield. Journal of Mineralogy and Petrology, 29(2), 78-83.

Li, W. H., Pang, J. G., Cao, H. X., Xiao, L., & Wang, R. G. (2009). Sedimentary system and paleogeography evolution of late Triassic in Ordos Basin. Journal of Northwest University (Natural Science), 39(3), 501-506.

Li, Y. L., & Yang, D. Q. (2003). Sensitivity evaluation on Jurassic system low permeability reservoir in Ridges Basin. Journal of Mineralogy and Petrology, 23(1), 77-80.

Moore, T. A. (2012). Coalbed methane: A review. Int. J. Coal Geol, 101, 36-81.

Pan, Z. J., Connell, D., Camilleri, M., (2010). Laboratory characterisation of coal reservoir permeability for primary and enhanced coalbed methane recovery. Int. J. Coal Geol, 82, 252-261.

Passey, Q. R., & Creaney, S. (1990). A practical model for organic richness from porosity and receptivity logs. AAPG Bulletin, 74(12), 1777-1794.

Peng, C.Y., Yan, B. J. N., & Li, Y. F. (1999). New method on prediction for potential sensitivity damage of reservoir. Drilling fluid and Completion Fluid, 16(2), 1-7.

Peters, K. E., Walters, C. C., & Moldowan, J. M. (2005). The biomarker guide: Volume 2, biomarkers and isotopes in petroleum systems and earth history (pp.475-625, 2nd ed.). Cambridge: Cambridge University Press.

Pillalamarry, M., Harpalani, S., & Liu, S. M. (2011). Gas diffusion behavior of coal and its impact on production from coalbed methane reservoirs. Int. J. Coal Geol, 86, 342-348 .

Qi, Y. L., Guo, Z. Q., Chu, M. J., Chen, D. X., & Zhang, Z. Y. (2013). Cl^- evolution mechanism analysis and significance for late Triassic extension period Cl in Ordos Basin. Lithologic Reservoirs, 25(5), 18-23.

Rachmat, S., Pramana, A., Febriana, L. (2012). Indonesia’s unconventional resources, modified resource triangle, and a typical example of stimulation of coalbed methane reservoir. Mod. Appl. Sci., 6(6), 99-111.

Ruan, C. D., & Ward, C. R. (2002). Quantitative X-ray powder diffraction analysis of clayminerals in Australian coals using Rietveld methods. Appl. Clay Sci., 21, 227-240.

Saulsberry, J. L., Schafer, P. S., & Schraufnagel, R. A. (1996). A guide to coalbed methane reservoir engineering. Gas Research Institute.

Shi, J. Q., & Durucan, S. (2004). Drawdown induced changes in permeability of coal beds: A new interpretation of the reservoir response to primary recovery. Transport in Porous Media, 56(1), 1-16. doi:10. 1023/B:TIPM. 00000. 18398. 19928. 5a

Valdya, R. N., & Fogler, H. S. (1992). Fines migration and formation damage: Influence of pH and Ion exchange. SPE Production Engineering, 7(4), 325-330.

Wang, J., Zhao, Y. C., Liu, H., & Wang, J. H. (2006). Main Control Factors of “Acidity and Alkalinity” Superposition Dissolutions for Upper Paleozoic Sandstone Reservoir in Tabamiao Area of Ordos Basin. Geoscience-Journal of China University of Geosciences, 31(2), 221-228.

Ward, C. R., Taylor, J. C., Matulis, C.E., & Dale, L. S. (2001). Quantification of mineral matter in the Argonne premium coals using interactive Rietveld-based X-ray diffraction. Int. J. Coal Geol, 46, 67-82.

Wei, Z. Y., Yao, G. Q., He ,S., Zhou, F. D., Zhao, Z. K., Jiang, T., & Miao, H. B. (2008). Digenesis Evolution History and Digenesis Mode for Chaluhe Faulted Depression Reservoir in Yitong Graben. Journal of Geosciences, 33(2), 227-231.

Zhao, X. Y., Luo, J. C., & Yang, F. (2005). Application on mineral research for oil and gas exploration in Tarim Basin. Xinjiang Petroleum Geology, 26(5), 570-576.

Zhou, F. D., Yao, G. Q., Chen, J. X., Zhao, Z. K., Jiang, T., & li, B. C. (2007). Analysis and Prediction on sensitivity influence factors for Chaluhe Fault Depression in Low Permeability Reservoir, Liangjia-Xinanbao Area. Journal of Mineralogy and Petrology, 27(3), 101-105.

Zhou, F. D., Yao, G. Q., Wang, G. C., Zhao, Z. K., Wang, L. W., & Miao, H. B. (2007). Elman neural networks applied in low-permeability reservoir sensitivity prediction. Geological Science and Technology Information, 26(6), 91-94.