Selection of OBM salinity through effective osmotic pressure evaluation in carbonera shale for colombian foothills

IF 0.5 4区工程技术 Q4 ENERGY & FUELS

Ct&f-Ciencia Tecnologia Y Futuro Pub Date : 2010-06-30 DOI:10.29047/01225383.436

William-Armando Fernández-Vera, R. Corzo, N. Saavedra

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引用次数: 0

Abstract

Wellbore instability in shales is attributed to many factors. Two of them are mechanical effects and physico-chemical effects. Drilling and drilling fluid cause physico-chemical interaction and the flux of water and ions that may alter the shale stress state through pore pressure and shale strength. This paper presents the analysis of the chemical osmosis phenomenon between drilling fluids and shale formations to evaluate the chemical parameters necessary for modeling the aqueous flux. These parameters are the drilling fluid activity (Adf), shale activity (Ash) and membrane efficiency (ME). This work also characterizes the shales for drilling purposes and describes an integrated methodology to obtain the magnitude of the chemical parameters. Furthermore, it is stated how the generation of effective osmotic pressure between the formation and drilling fluid define the water flux direction. Finally, the application of the results of the chemical analysis to Carbonera shale is presented. The design of laboratory tests for two mud formulations, Mud A and Mud B, and the field application is also showed. The Mud A is a balanced activity mud and the Mud B is a high salt concentration mud which may produce water flux out of the shale formation (dehydration) during drilling, in some sections of the wellbore, increasing the formation strength. The results presented in this paper will help to reduce the risks associated with wellbore instability during the drilling of shale formations and thereby lowering the overall non-productive time and reducing drilling costs.

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通过有效渗透压评价选择哥伦比亚山麓石炭系页岩OBM盐度

页岩井筒失稳的原因有很多。其中两种是机械效应和物理化学效应。钻井与钻井液之间的物理化学相互作用以及水和离子的通量可能通过孔隙压力和页岩强度改变页岩应力状态。本文分析了钻井液与页岩地层之间的化学渗透现象，以评估模拟含水通量所需的化学参数。这些参数分别是钻井液活度(Adf)、页岩活度(Ash)和膜效率(ME)。这项工作还描述了用于钻井目的的页岩特征，并描述了一种获得化学参数大小的综合方法。此外，还阐述了地层与钻井液之间有效渗透压的产生是如何决定水通量方向的。最后，介绍了化学分析结果在石炭纪页岩中的应用。介绍了泥浆A和泥浆B两种泥浆配方的室内试验设计和现场应用情况。泥浆A是一种平衡活性泥浆，泥浆B是一种高盐浓度泥浆，在钻井过程中，在井筒的某些部分可能会产生从页岩地层中流出的水通量(脱水)，从而增加地层强度。本文的研究结果将有助于降低页岩地层钻井过程中与井筒不稳定相关的风险，从而减少总体非生产时间，降低钻井成本。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Ct&f-Ciencia Tecnologia Y Futuro Energy-General Energy

CiteScore

1.50

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： The objective of CT&F is to publish the achievements of scientific research and technological developments of Ecopetrol S.A. and the research of other institutions in the field of oil, gas and alternative energy sources. CT&F welcomes original, novel and high-impact contributions from all the fields in the oil and gas industry like: Acquisition and Exploration technologies, Basins characterization and modeling, Petroleum geology, Reservoir modeling, Enhanced Oil Recovery Technologies, Unconventional resources, Petroleum refining, Petrochemistry, Upgrading technologies, Technologies for fuels quality, Process modeling, and optimization, Supply chain optimization, Biofuels, Renewable energies.