Bottom Hole Pressure Management in a Highly Permeable and Narrow Margin MPD Operation

Oseme, Ugochukwu; Awe, Sunday; Amah, Obinna; Erinle, Adeyemi; Akinfolarin, Ayodele; Ibrahim, Timothy; Roes, Vincent

doi:10.2118/afrc-2571990-ms

All Days 2016

DOI: 10.2118/afrc-2571990-ms

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Bottom Hole Pressure Management in a Highly Permeable and Narrow Margin MPD Operation

Ugochukwu Oseme

Sunday Awe

Obinna Amah

et al.

Abstract: Application of Managed pressure drilling (MPD) technology with other techniques to maintain constant Bottom Hole pressure (BHP) has been found to enhance drilling operations in applications where the margin between the pore pressure and fracture gradient is narrow and the reservoir permeability is high. Classic examples of such applications are deep water drilling, high pressure and high temperature (HPHT) regime and depleted reservoir environments. In the Niger Delta, HPHT reservoirs can be fou… Show more

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Cited by 3 publications

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Optimizing MPD Performance in Highly Permeable Exploratory HPHT Reservoirs: Dealing with Human Factor and Technology Limitations

Awe

Akinfolarin

Erinle

et al. 2018

Day 1 Tue, April 17, 2018

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The management of human factor and the utilization of advanced Annular Pressure Monitoring (APM) tool enhanced the performance of Managed Pressure Drilling (MPD) in a highly permeable and narrow margin high pressure (HP)exploration gas wells in the Niger Delta. The pore pressure prognosis (PPP) indicated narrow drilling window in the HP section which necessitated the deployment of MPD for safe project execution. The MPD mud design entailed drilling with a mud weight that balanced the expected pore pressure prognosis (PPP) and the application of MPD surface back pressure (SBP) to balance the highest PPP case. During the drilling of the first of a three-well-campaign, a kick was taken with pore pressure equivalent to the highest predicted case. The evaluation of the pre-kick Equivalent Static Density (ESD) data indicated that the bottom hole pressure (BHP) was not maintained at the programmed set point unknown to the MPD operator. Transient dips in the BHP below the set point and pore pressure resulted to significant gas influx from the gas reservoir with permeability of 124 - 204mD and reservoir mobility of 112 – 1000mD/cp. Incident causal analysis revealed the contribution of human factor and limitations of conventional APM tool. This paper details how human factor was effectively managed using procedures and training, and how the advanced APM tool enhanced MPD process optimization in the second deployment resulting in the achievement of BHP values within the range for safe drilling.

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Optimizing MPD Performance in Highly Permeable Exploratory HPHT Reservoirs: Dealing with Human Factor and Technology Limitations

Awe

Akinfolarin

Erinle

et al. 2018

Day 1 Tue, April 17, 2018

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Pressure Relief Management Philosophy for MPD Operations on Surface Stack HPHT Exploration Wells

Benyeogor¹,

Jambol²,

Amah³

et al. 2019

Day 3 Wed, August 07, 2019

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Managed pressure drilling (MPD) is an adaptive drilling technique used to improve the economics and to mitigate risks associated with drilling high pressure and high temperature (HPHT) exploration wells where the drilling window is often narrow. The technique involves the combination of surface back pressure and fluid hydrostatic column to provide the required bottom hole pressure for safe drilling. Typical MPD equipment spread includes rotating control device (RCD), chokes, high pressure lines and gate valves with Pressure relief valves (PRVs) incorporated. The primary purpose of the PRV is to protect the MPD surface equipment and the formation from being overpressured. The relief valve achieves this by bypassing the normal fluid flow path for MPD operations and relieving the system pressure to the rig Mud gas separator (MGS) through a dedicated line. Each time a PRV is activated the resulting loss of surface back pressure increases the risk of taking a kick. On the other hand, when a PRV is not activated, an excessive increase in surface pressure raises the risk of formation fracture leading to losses. Therefore, the performance of the PRV has an immense impact on assessing the risk of a well control situation, which may be caused by either loses due to formation breakdown and consequently a kick from loss of the hydrostatic pressure component of the equivalent surface density (ESD) or an influx as a result of loss of surface back pressure component of the ESD due to loss of integrity of surface equipment). Pressure Relief Management philosophy generally covers decisions such as which parts of the well system (surface and subsurface) are to be preferentially protected by the PRVs, selection of activation pressure for high level alarms, types, number and setpoints of PRVs in the MPD system during different phases of the drilling operations - drilling, connections and tripping, and MPD choke full-opening pressure. These values are dependent on formation integrity test (FIT), mud weight, drilling window, annular friction pressure and operating envelope of RCD. The set points require adjustment depending on the hole size and flow rate and may be different during completion and well control operations. This paper describes the Pressure Relief Management philosophy for a HPHT well drilled in the Niger delta. It looks at factors that drive the high-pressure alarm setting values, choice of PRV types, placement and the part of the well system being protected, PRV tripping and reset values, and MPD choke full opening pressures. It also describes the challenges and risk assessment that influenced the selection of set points (single or dual setpoints) for different phases of the drilling operations.

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Pressure Losses Calibration in Managed Pressure Drilling

Ilin

Brana

Rostami

et al. 2020

Day 2 Tue, May 05, 2020

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Managed Pressure Drilling (MPD) usage is in increasing demand in both offshore and onshore market – especially for wells with narrow drilling pressure margins. Maintaining desired constant Bottom-Hole Pressure (BHP) within given range during MPD operation requires accurate hydraulic modeling for frictional pressure losses. Surface BackPressure (SBP) and StandPipe Pressure (SPP) data, measured in real-time, allows the calibration of frictional pressure losses and an estimation of BHP more accurately. An estimation of SPP is calculated based on integration from the measured SBP back to the inlet in the hydraulics model. The pressure loss increment in the hydraulics model is calculated based on a difference between the measured and estimated SPP value. The system parameters are monitored during drilling and could be adjusted based on the hydraulics model corrected for the pressure loss. The frictional pressure loss due to the drilling pipe rotation could be calibrated by analyzing a difference between the measured and estimated SPP for two operations: without rotation and with rotation. This work underscores the development and usage of advanced hydraulics modeling to accurately calculate BHP during MPD operations. In current hydraulics, mathematical models have been developed to account for various operating parameters, wellbore geometry and fluid properties. This is an enabler to estimate pressure, density, rheology, temperature, and cuttings distributions within the wellbore, drill string and surface equipment more precisely. The frictional pressure loss model includes rotational pressure losses, local pressure losses at special tools and tool joints. This model is based on empirical sub-models which require experimental verification for accuracy. The results of the BHP, calculated with a calibrated hydraulic model, are compared with corresponding results calculated with the uncalibrated model. The use of the pressure calibration for the hydraulics model allows estimating BHP with less error. Recommendations are presented for the accurate mathematical modeling and their applicability and limitations for successful MPD operations.

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Bottom Hole Pressure Management in a Highly Permeable and Narrow Margin MPD Operation

Cited by 3 publications

References 3 publications

Optimizing MPD Performance in Highly Permeable Exploratory HPHT Reservoirs: Dealing with Human Factor and Technology Limitations

Optimizing MPD Performance in Highly Permeable Exploratory HPHT Reservoirs: Dealing with Human Factor and Technology Limitations

Pressure Relief Management Philosophy for MPD Operations on Surface Stack HPHT Exploration Wells

Pressure Losses Calibration in Managed Pressure Drilling

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