Effect on the performance of drilling fluids at downhole rock surfaces at low temperatures

Mingming Zheng, Guosheng Jiang, Tianle Liu, Fulong Ning, Ling Zhang, V. F. Chikhotkin

Journal of Earth Science ›› 2016, Vol. 27 ›› Issue (5) : 856-863.

Journal of Earth Science ›› 2016, Vol. 27 ›› Issue (5) : 856-863. DOI: 10.1007/s12583-016-0719-z
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Effect on the performance of drilling fluids at downhole rock surfaces at low temperatures

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Abstract

To maintain gas hydrate stability, low-temperature drilling fluids and high drilling speeds should be used while drilling in gas hydrate-bearing sediments. The effect of the drilling fluid on downhole rock surfaces at low temperatures is very important to increase the drilling rate. This paper analyzed the action mechanism of the drilling fluid on downhole rock surfaces and established a corresponding evaluation method. The softening effect of six simulated drilling fluids with 0.1 wt.% of four common surfactants and two common organic salts on the downhole rock surface strength was evaluated experimentally using the established method at low temperature. The experimental results showed that the surfactants and organic salts used in the drilling fluids aided in the reduction of the strength of the downhole rock surface, and the established evaluation method was able to quantitatively reveal the difference in the softening effect of the different drilling fluids through comparison with water. In particular, the most common surfactant that is used in drilling fluids, sodium dodecyl sulfate (SDS), had a very good softening effect while drilling under low-temperature conditions, which can be widely applied during drilling in low-temperature formations, such as natural gas hydrate-bearing sediments, the deep seafloor and permafrost.

Keywords

gas hydrate bearing sediments / low temperature drilling fluid / performances / downhole rock surface strength / influence mechanism

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Mingming Zheng, Guosheng Jiang, Tianle Liu, Fulong Ning, Ling Zhang, V. F. Chikhotkin. Effect on the performance of drilling fluids at downhole rock surfaces at low temperatures. Journal of Earth Science, 2016, 27(5): 856‒863 https://doi.org/10.1007/s12583-016-0719-z

References

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Bai Y. H., Ye C. M., Li Q. P., . Advances in Exploitation Models of Gas Hydrate and Their Prospects. China Offshore Oil and Gas, 2009, 21(4): 251-256.
Cao D. Y., Liu T. J., Wang D., . Analysis of Formation Conditions of Natural Gas Hydrate in Muli Coalfield, Qinghai Province. Coal Geology of China, 2009, 21(9): 3-6.
Cardoso J. J. F., Spinelli L. S., Monteiro V., . Influence of Polymer and Surfactant on the Aphrons Characteristics: Evaluation of Fluid Invasion Controlling. Express Polymer Letters, 2010, 4(8): 474-479.
CrossRef Google scholar
Cohen, J. H., Williams, T. R., Kadaster, A. G., et al., 2011). Hydrate Core Drilling Tests. [2011-1-7] http://www.netl.doe.gov/technologies/oil-gas/publications/Hydrates/pdf/hyd-core-drill-maurer.pdf
Growcock F. Enhanced Wellbore Stabilization and Reservoir Productivity with Aphron Drilling Fluid Technology, 2005.
Jiang G. S., Liu T. L., Ning F. L., . Polyethylene Glycol Drilling Fluid for Drilling in Marine Gas Hydrates-Bearing Sediments: An Experimental Study. Energies, 2011, 4(1): 140-150.
CrossRef Google scholar
Kusov N. F., Edelstein O. A., Shobolova L. P. Destruction of Hard Rock with the Use of Surfactants. Scientific Journal, 2002, 212: 71-76.
Kutasov I. M., Eppelbaum L. V. Cementing of Casing in Hydrocarbon Wells: The Optimal Time Lapse to Conduct a Temperature Log. Oil Gas European Magazine, 2013, 39(4): 190-193.
Levsheva E. L. Overview of Analytical Research Results for Improving Rock Destruction Efficiency and Prospects of Surfactants Using in Deep Wells Drilling, 2011, 37-40.
Li G. Z., Xu J. Application and Principle of Surfactants in Oil Field. Advances in Fine Petrochemicals, 2004, 2: 1-6.
Li Y. H., Song Y. C., Yu F., . Effect of Confining Pressure on Mechanical Behavior of Methane Hydrate-Bearing Sediments. Petroleum Exploration and Development, 2011, 38(5): 637-640.
CrossRef Google scholar
Mahmoud S. A., Dardir M. M. Synthesis and Evaluation of a New Cationic Surfactant for Oil-Well Drilling Fluid. Journal of Surfactants and Detergents, 2011, 14(1): 123-130.
CrossRef Google scholar
Makogon Y. F. Natural Gas Hydrates—A Promising Source of Energy. Journal of Natural Gas Science and Engineering, 2010, 2(1): 49-59.
CrossRef Google scholar
Meng L. Y., Zhang X. H., Zhang Q. L., . Discussion on the Influencing Factors on the Performance of Surfactants Used in Drilling Fluid. Journal of Chemical Industry & Engineering, 2013, 34(5): 45-48.
Nikolaev N. I., Levsheva E. L. Results of Experimental Studies on the Effectiveness of Rock Hardness Reagents-Reducers in Drilling Fluids. Oil Engineer. Scientific and Technical Journal M., 2011, 3: 32-35.
Ning F. L., Wu N. Y., Zhang K., . Estimation of In-Situ Mechanical Properties of Gas Hydrate-Bearing Sediments by Well Logging. Petroleum Exploration and Development, 2013, 40(4): 507-512.
CrossRef Google scholar
Rebinder P. A., Schreiner L. A., Zhigach K. F. Rock Hardness Reducers in Drilling—A Physicochemical Method to Facilitate Mechanical Destruction of Hard Rock while Drilling, 1994, 199.
Sloan E. D. Fundamental Principles and Applications of Natural Gas Hydrates. Nature, 2003, 426(6964): 353-363.
CrossRef Google scholar
Sloan E. D. Introductory Overview: Hydrate Knowledge Development. American Mineralogist, 2004, 89: 1155-1161.
CrossRef Google scholar
Tan C. P., Clennell M. B., Tohidi B. Managing Wellbore Instability Risk in Gas-Hydrate Bearing Sediments, 2005, 1125-1132.
Tsuji Y. Japan Drills, Logs Gas Hydrate Wells in the Nankai Trough. Oil & Gas Journal, 2005, 103(34): 37-42.
Uchida A., Ebinuma A., Ishizaki T. Dissociation Condition Measurements of Methane Hydrate in Confined Small Pores of Porous Glass. J. Phys. Chem., 1999, 103: 3659-3662.
CrossRef Google scholar
Yan J. N. Drilling Fluid Technology, 2001, Dongying: China University of Petroleum Press, 5-10.
Zatsepina O., Buffett B. A. Experimental Study of the Stability of CO2 Hydrate. Fluid Phase Equil., 2001, 192(1): 85-102.
CrossRef Google scholar
Zhang, Y. Q., Sun, J. H., Jia, Z. Y., 2010). Research and Application of Gas Hydrate Drilling Technology in Land Permafrost in China. Exploration Engineering (Drilling & Tunneling), (S1): 22–26 (in Chinese with English Abstract)
Zhang X. T., Norman R. M. Variation in Wetting Behavior of Mixed Wet-Ores Resulting from Probe Oil Solvency and Exposure to Synthetic Oil-Based Mud Emulsifiers. J. Petroleum Sci. Eng., 2006, 52: 149-160.
CrossRef Google scholar
Zhu Y. H., Zhang Y. Q., Wen H. J. An Overview of the Scientific Drilling Project of Gas Hydrate in Qilian Mountain Permafrost, Northwestern China. Geological Bulletin of China, 2011, 30(12): 1816-1822.

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