Abstract
One of the most significant problems in oil and gas sector is the swelling of shale when it comes in contact with water. The migration of hydrogen ions (H+) from the water-based drilling fluid into the platelets of shale formation causes it to swell, which eventually increases the size of the shale sample and makes it structure weak. This contact results in the wellbore instability problem that ultimately reduces the integrity of a wellbore. In this study, the swelling of a shale formation was modeled using the potential of first order kinetic equation. Later, to minimize its shortcoming, a new proposed model was formulated. The new model is based on developing a third degree polynomial equation that is used to model the swelling percentages obtained through linear dynamic swell meter experiment performed on a shale formation when it comes in contact with a drilling fluid. These percentages indicate the hourly change in sample size during the contact. The variables of polynomial equation are dependent on the time of contact between the mud and the shale sample, temperature of the environment, clay content in shale and experimental swelling percentages. Furthermore, the equation also comprises of adjustable parameters that are fine-tuned in such a way that the polynomial function is best fitted to the experimental datasets. The MAE (mean absolute error) of the present model, namely Scaling swelling equation was found to be 2.75%, and the results indicate that the Scaling Swelling equation has the better performance than the first order kinetics in terms of swelling predication. Moreover, the proposed model equation is also helpful in predicting the swelling onset time when the mud and shale comes in direct contact with each other. In both the cases, the percentage deviation in predicting the swelling initiation time is close to 10%. This information will be extremely helpful in forecasting the swelling tendency of shale sample in a particular mud. Also, it helps in validating the experimental results obtained from linear dynamic swell meter.
Highlights
Drilling fluid is considered as one of the most important segment in drilling industry
The major drawback that is associated with this equation is not taking into the account the effect of temperature, swelling time, clay content that is present in the shale sample and the experimental results obtained through linear dynamic swell meter (LDSM)
The first order kinetic model developed by Maghrabi et al (2013) in 2013 was the fundamental model that uses concept of curve fitting for the modeling of shale swelling through linear dynamic swell meter experimental results
Summary
Drilling fluid is considered as one of the most important segment in drilling industry. The major drawback that is associated with this equation is not taking into the account the effect of temperature, swelling time, clay content that is present in the shale sample and the experimental results obtained through LDSM. The first order kinetic model developed by Maghrabi et al (2013) in 2013 was the fundamental model that uses concept of curve fitting for the modeling of shale swelling through linear dynamic swell meter experimental results.
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