Engineered Wellbore Strengthening Application Enables Successful Drilling of Challenging Wells

An important measure for increasing oil and gas recovery is infill drilling. For mature fields, drilling and completion of new wells can be challenging due to a limited (or non-existent) operational window. The operational window is defined by an upper and a lower bound. The lower bound is usually based either on the pore pressure or the borehole stability limit, whichever is higher. The upper bound is an estimate of the maximum hydraulic pressure the wellbore wall can be exposed to without experiencing fluid loss (called Fracture Gradient, FG). Losses can occur in all types of reservoirs, but depleted reservoirs are more prone to losses because of reduced pore pressure and the decreasing in-situ stress. With reducing stress, the fracture propagation pressure decreases, and it becomes easier to open and drive a hydraulic fracture. A mitigating factor is to reduce mud weight, but this is not always possible in cases of differential depletion where there can be a complex distribution of pore pressure and fracturing pressure along the well. In many such cases, a FG much larger than the fracture propagation pressures in the low-pressure zones is required so that a mud weight can be selected that will balance the high-pressure zones. Such strategies then rely on the extra "strength" provided by the wellbore and specialized particles. Lost-circulation issues lead to non-productive rig time and direct costs associated with lost volumes of mud. If not managed correctly, they may also lead to loss of well/technical sidetrack and, in the worst case, serious well control incidents. Understanding the mechanisms in play is crucial for curing losses, since lost circulation materials used to treat losses caused by induced fractures are not necessarily effective against losses in naturally fractured rocks because of differences in fracture aperture and connectivity. Numerical modelling and analysis of lost-circulation mechanisms are presented in this article. Losses at so-called weak points are addressed and analysis of field data is discussed. Different potential influences on the FG are considered. Effects of varying rock properties and reservoir depletion, and different borehole geometries are modelled and discussed. Shale/sand interfaces are modelled as potential weak-zones and the resulting shear stresses across such interfaces are analyzed during drill-out. We find that such interfaces can be potential weak-zones and that boreholes with non-circular shape are more likely to experience tensile fracturing and mud losses. This highlights the challenges when estimating FG for heavily depleted reservoirs and it confirms the understanding that poor drilling practice which can create weak-points can directly reduce the FG (in addition to unfavorable ECD conditions in well).

show abstract

Understanding Loss Mechanisms: The Key to Successful Drilling in Depleted Reservoirs?

Scheldt

Andrews

Lavrov

2019

SPE Drilling &Amp; Completion

View full text Add to dashboard Cite

Summary Mud losses are frequently observed when drilling in depleted formations. This is because of the decrease in the minimum in-situ stress during depletion. As a result of this decrease, the lost-circulation pressure—or fracture gradient (FG)—decreases, and the operational mud-weight window shrinks. Losses in such formations are often observed when drilling through sand/shale sequences. Preventing and curing losses requires a sound understanding of loss mechanisms. In this study, we investigate several mechanisms that might be responsible for the elevated risk of mud losses in differentially depleted sand/shale sequences. Numerical models of synthetic cases representative of lost-circulation scenarios in a high-pressure/high-temperature (HP/HT) field in the North Sea, under normal faulting conditions, are set up using the finite-element method. The simulations reveal that shear displacement at the horizontal sand/shale interfaces is unlikely to cause losses. On the other hand, shear displacement and losses might be induced at high-angle sand/shale interfaces, such as those found near faults. In addition, faults introduce an extra complexity to the stress distribution and stress-path coefficients. Stress anisotropy near faults might increase during depletion, making both lost-circulation issues and borehole-stability problems worse. The zone most prone to lost circulation in a faulted formation is located in depleted sand adjacent to the fault. The loss mechanism here is because of drilling-induced fractures (DIFs). In addition, depletion itself might induce fractures in shale adjacent to the depleted sand and located across the fault from it. Such fractures might then serve as escape paths for the drilling fluid during infill drilling. The loss mechanism here is caused by pre-existing, depletion-induced fractures. These findings are in agreement with field observations. A noncircular (elliptic or irregular) borehole cross section is found to reduce the fracture-initiation pressure (FIP). An irregular borehole cross section is, thus, another possible mechanism behind irregular loss patterns observed in depleted fields. The results from the study are important for establishing best practices when drilling in depleted formations.

show abstract

Engineered Wellbore Strengthening Application Enables Successful Drilling of Challenging Wells

Cited by 5 publications

References 11 publications

Wellbore Strengthening for Addressing Lost Circulation in Fractured Formations: A Comprehensive Review

Wellbore Strengthening for Addressing Lost Circulation in Fractured Formations: A Comprehensive Review

Understanding Loss Mechanisms – The Key to Successful Drilling in Depleted Reservoirs?

Understanding Loss Mechanisms: The Key to Successful Drilling in Depleted Reservoirs?

Contact Info

Product

Resources

About