Application of Underbalanced Coiled Tubing Drilling Technology to Enhance Gas Production in Deep Carbonate Reservoirs

The nature of tight gas reservoir consists of heterogeneous sub-units separated by impermeable denses and various depletion level has become the greatest challenge on how to exploit this typical reservoir at its maximum. Despite maximum reservoir contact is the best method to deliver the highest well production, this paper tries to tell another success story about UBCTD applied in a triple lateral well which can deliver greater productivity than a normal overbalanced multilateral well. The study methodology begins with the evaluation of the current remaining potential sweetspots throughout the reservoir. The assisted history matching is used to generate 3 different model realizations: Low - Mid - High case that can map-out sweetspot distribution called Simulation Opportunity Index (SOI) map. SOI integrates 3 independent components selected from static and dynamic parameters: reservoir permeability-thickness, movable gas and reservoir pressure from a historically-matched dynamic model. One particular area is then selected and evaluated furthermore for the final new well and trajectory placement. The well was drilled as a triple lateral with one of the lateral was fully placed in prime sub-unit that likely holds the potential remaining sweetspot in the area according to SOI method with expectation to maximize its recovery. During the drilling, UBCTD technique was implemented because it offers several advantages such as reduction of formation damage, reduction of drilling fluid loss into formation, avoiding losses-related drilling problems and risk of differential sticking and creating cost saving for completion and stimulation requirements. Earlier study in the field signified that generally, the well productivity is strongly influenced by the type of the lateral and the geological structure. For instance, the triple lateral well located at higher structure normally gives higher productivity than the triple lateral well located underneath it. Theoretically, higher productivity will be given by the triple lateral compared to the situation if the same area is developed by dual lateral or even by the single lateral well. Currently, the implementation of UBCTD in this triple lateral well was confirmed to provide better productivity up to double exceeding a conventional overbalanced with the same well laterals. Greater initial gas production rate with high THP was evidenced during the well clean-up. UBCTD application in tight gas reservoirs is not only aimed to improve the initial well productivity significantly beyond the conventional overbalanced well but it is also expected to create more equal pressure drawdown distribution along the lateral drain because of many given advantages as stated above. At last, cost saving can be performed because the operating cost which is usually spent on normal wells for well stimulation can be reduced.

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Deliver the Best Production Potential of the Multilateral Well in Tight Gas Carbonate Reservoir with Underbalanced Coiled Tubing Drilling (UBCTD)

Bernadi

Shehhi

Ameri

et al. 2023

Day 2 Tue, March 14, 2023

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Geothermal Energy: A Novel Coiled Tubing Technology Transition

Torres,

Livescu,

Carlisle

et al. 2024

SPE/ICoTA Well Intervention Conference and Exhibition

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Coiled tubing has historically been a supporting technology deemed to interact closely with other technologies, given its versatility on equipment, pipe size and configuration, fluids used, tools conveyance, and interaction with the reservoir. Its applicability and value for hydrocarbon production have been vastly documented from drilling and completions to production enhancement and well abandonment. This paper describes a novel application, where an ultra-compact coiled tubing unit (UCCTU) was designed and built for shallow geothermal well drilling and reservoir/aquifer characterization, as part of a project to deliver geothermal energy in dense urban areas across the United States, decarbonizing buildings and reducing their dependance on the electrical grid. The UCCTU was designed and built in six months, where a conventional skid coiled tubing unit was customized for this shallow geothermal drilling application. Considering inner city weight, width, length, and height limitations, two complementing trucks were built. The equipment includes a control cabin, wet kit, coiled tubing reel, 2 3/8-in.coiled tubing with wired downhole telemetry, injector head, stripper, crane, and fluid pump, built considering the smallest footprint possible to ease access in streets and avenues. Engineering was performed to deliver the unit within the required time frame and evaluate modifications needed on the equipment to build this prototype, which would be used to drill wells and log during the process by means of the downhole telemetry. The unit went into field testing, running 2-3/8-in pipe with a downhole motor, drilling bit, and logging tools. At the time of writing this abstract, a total of four wells were drilled, which provided improvement opportunities: Unit design improvementsRig up and rig down process.Drilling and logging operational efficiencies.Location set up and layout.Aquifer characterization Several other details are included regarding shallow geothermal well design for direct heating and cooling applications, and tensile force analysis cases for certain coiled tubing configurations. This coiled tubing unit application is a disruptive step change on how the units can be designed for shallow well drilling, how they can be made more efficient, and most importantly, how can we transition oil & gas (O&G) proven technologies, such as coiled tubing, drilling, and logging, into geothermal energy production.

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An Integrated Workflow for Improved Lateral Placement in Underbalanced Coiled Tubing Drilling Operations

Al Abdrabalnabi,

Abu Alsaud,

Malik

2024

SPE/IADC Managed Pressure Drilling and Underbalanced Operations Conference and Exhibition

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This paper describes an integrated workflow that was developed to identify sweet spot and maximize lateral placement in underbalanced coiled tubing drilling (UBCTD). As fields mature and become more challenging, UBCTD becomes an effective solution to extract hydrocarbon. In some implementations, UBCTD encounters drilling challenges that result in shorter laterals or lower net-to-gross ratio than planned. Effective lateral placement precision in sweet spot is one of the main requirements to optimize productivity of oil and gas reservoirs. The constructed workflow maps key operational indicators extracted from offset wells to drive optimized well placement and maximized gas output. The workflow involves selecting key indicators from multiple offset wells to identify vertical and spatial variations. These variation profiles are generated based on a pattern and trends with highest success rates across available data. Based on the ideal productivity profile identified and the matched target well placement, the operational plan is then integrated with seismic data to boost lateral placement accuracy across the target. Developed data maps and actual gas rate are assessed to verify placement accuracy, and call for decisions to adjust well trajectory plans in real time. The introduced solution has demonstrated improvements in lateral placement by utilizing key operational indicators from offset wells data. The workflow was conducted on a synthetic thin carbonate reservoir box, where the generated stratigraphic window was adjusted based on an optimal performance data. The data collected during UBCTD operations was further inverted to enhance and improve operations. The developed workflow pinpoints operations variation and allows steering corrections to place the lateral within the expected target, where gas flow readings will confirm reliability of the operation parameters and thus model robustness and validity. The process implemented focuses on integrating real-time data to optimize predictive models and avoids drilling non-reservoir footage. In addition, the workflow accounts for time delay challenge between bit position and logging tools in the bottom hole assembly during data acquisition.

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Application of Underbalanced Coiled Tubing Drilling Technology to Enhance Gas Production in Deep Carbonate Reservoirs

Cited by 6 publications

References 7 publications

Deliver the Best Production Potential of the Multilateral Well in Tight Gas Carbonate Reservoir with Underbalanced Coiled Tubing Drilling (UBCTD)

Deliver the Best Production Potential of the Multilateral Well in Tight Gas Carbonate Reservoir with Underbalanced Coiled Tubing Drilling (UBCTD)

Geothermal Energy: A Novel Coiled Tubing Technology Transition

An Integrated Workflow for Improved Lateral Placement in Underbalanced Coiled Tubing Drilling Operations

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