Drilling-Fluid Design for Challenging Wells in the Andean Mountain Region

Ramirez, Mario Alfredo; Clapper, Dennis; Kenny, Patrick

doi:10.2118/102206-ms

Cited by 7 publications

(2 citation statements)

References 16 publications

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“…The aluminated complex is soluble in the mud but precipitates it enters the shale matrix due to reduction in the pH,reaction with multivalent cations existing in the formation fluids or combination of both. A recent,independent study of pore pressure transmission 7,8 and membrane efficiency in shale concluded that aluminates (and silicates) provide the highest membrane efficiency of WBM. An independent test conducted by OGS by using Downhole simulation cells demostrated the superior performance of aluminum complex and silicate muds over other water-based systems as indicated in the figures Impermeable Barrier Formation.…”

Section: Spe/iadc 108213mentioning

confidence: 99%

Aluminum-Based HPWBM Successfully Replaces Oil-Based Mud to Drill Exploratory Well in the Magellan Strait, Argentina

et al. 2007

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TX 75083-3836 U.S.A., fax 1.972.952.9435. AbstractTraditionally, Oil Base Mud (OBM) has been used by a major operator to drill horizontal wells in the Magellan Strait, Argentina. The operator was faced with additional challenges when drilling an exploratory well due to environmental concerns in a highly sensitive area and evaluation problems related to the use of OBM. Significant advances in water based drilling fluid design in the recent years have allowed water-based drilling fluid performance to approach that of OBM. This presented the operator and drilling fluids supplier with the opportunity of evaluating the application of water base drilling fluid on this well. The planning stage included laboratory testing, review of historical data and an evaluation of experience with similar shales in the area. A high performance water base drilling fluid containing both clay and shale stabilizers, an ROP enhancer and sealing agents was selected to drill the well. This paper presents the laboratory and field data generated during this project. The well was drilled through notoriously troublesome shales to total depth without the wellbore stability problems associated with more conventional water based muds. Gas kicks were controlled with no fluid solubility problems and the fluid exhibited excellent properties even when pressure parameters escalated higher than planned, requiring a higher mud density and high degree of temperature stability. The operator's expectations were met in this very difficult well including minimization of bit balling, near gauge hole and improved ROP in conjunction with optimum hydraulics.The evidence gathered on this project shows that a properly designed water base mud is a viable alternative to OBM in areas where environmental restrictions and formation evaluation problems are a concern.

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Section: Spe/iadc 108213mentioning

confidence: 99%

Aluminum-Based HPWBM Successfully Replaces Oil-Based Mud to Drill Exploratory Well in the Magellan Strait, Argentina

et al. 2007

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“…Their work lead to the use of water based mud (Barite) incorporated with Aluminum salt as an inhibitor and a stabilizer. (Ramirez, et al 2006) They conducted dispersion tests on the Napo shale, which showed 58.2% dispersion in fresh water, 38.2% dispersion in xanthan gum mud and 14.2% in the aluminum inhibitor mud.…”

Section: Previous Workmentioning

confidence: 99%

The Incorporation of Aluminum Hydroxide in Water Based Muds to Stabilize Marcellus Shale Drilling in West Virginia

Al-Fadhel¹

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Thesis submitted to the College of Human Resources and Education at West Virginia University in partial fulfillment of the requirements for the degree of Master of Science in Petroleum and Natural Gas Engineering Hussain Ali Al-Fadhel The purpose of this study was to develop a safe and environmentally acceptable water base mud that will be able to suppress swelling and promote stability to the West Virginian Marcellus shale. The problem was approached by utilizing aluminum precipitation chemistry in the drilling fluid, unlike the traditional cation-exchange approach. A dynamic swelling meter was designed by modifying a 0.001 mm resolution dial indicator and using a specially programmed smart cable connecting the dial indicator to a computer. The swelling data was acquired by the smart cable every six seconds. As a result, there were 14,400 measured points for each sample for the 24 hours test duration.

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