Healing Total Losses and Establishing Well Integrity with Engineered Fiber-Based Lost Circulation Control Spacer During Primary Cementing in UAE Offshore
Abstract: Lost circulation (LC) is an expensive and time-consuming problem. It's desirable to minimize losses before cement job to ensure good cement coverage and maximize well integrity. But quite commonly, wells experience induced losses just before cementing, during casing running and circulation. In such a scenario, the options to control losses have been few, with limited results. The paper demonstrates a viable solution that can be successfully applied to reduce or eliminate such induced losses during the cement j… Show more
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Cited by 3 publications
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Achievement of 7-In. Production Liner Cementing with Seamless HP Zonal Isolation Integrity Whilst Coping with Challenges of Well Ballooning and Influx
Successfully achieving primary cementing objective within a very narrow pore-fracture pressure window is a significant challenge for the industry. During the cementing operation, variations in the equivalent circulation density (ECD) above or below the formation's pore/fracturing gradients can lead to wellbore losses or gains. An additional phenomenon that may be observed in these types of operations is wellbore ballooning, where wellbore fluids enter the formation under dynamic overbalance circulating conditions, and then flow back into the wellbore once pumps are stopped, dynamic circulating pressure is removed, and bottom hole pressure (BHP) is reduced, mimicking indications of a kick but without continuous influx of formation fluids. Designing a proper cement job to achieve zonal isolation and meet primary objective in such a scenario requires this challenge to be addressed and a fit-for-purpose solution to be developed to limit any post placement flowback that may compromise the cement integrity and zonal isolation. A 7-in. liner was run inside an 8 ½-in. open hole (OH) that had been drilled to section depth with a very tight drilling pressure window between gains from and losses to the formation. Losses and subsequent ballooning related flows were observed during the drilling phase. To determine the exact drilling window available, dynamic flow tests were conducted before the cement job to simulate ECD, and the available operational pressure window was identified between 13.4 - 14.6 lbm/gal. This data was used as input to a proprietary cementing software simulator to model the dynamic pressures expected during the cement job. Due to the small available window, conventional rules for density hierarchy, which keeps +/- 1.0 lbm/gal density difference among each fluid in cementing jobs, could not be followed. Also, due to the relatively small annular clearance, dynamic fluid friction pressures and optimization of liner stand-off played a critical factor in the job design. A high-pressure lightweight cement slurry was developed in the laboratory, aiming to withstand bottom hole formation pressure at 5,500 psi and achieve tight ECD control to minimize losses to the formation. The slurry system was optimized to be placed safely in the wellbore without jeopardizing the critical cement properties required for the annular isolation across the complete production liner. Multiple simulations and sensitivity tests were run to provide the optimized placement of the cement slurry and avoid losses or gains throughout cement placement. As even very small volumes of loss and subsequent flowback could contaminate the cement slurry, the density of the spacer ahead of the lead slurry was also optimized and enhanced through the inclusion of loss circulation materials, specifically engineered fibers, to further mitigate potential losses to larger fractures. The 7-in. liner cement job was conducted as planned with the liner rotated throughout the cement job to enhance the mud removal and improve cement bond. No losses or ballooning were observed throughout the entire cement job. Playback simulation showed the cementing job was executed as designed. formation integrity test (FIT) and cement bond log (CBL) confirmed shoe integrity up to 6,000 psi and zonal isolation requirement across the target formations. Proper planning and analysis of dynamic pressures and accurate operational control allowed us to achieve the objectives of this challenging cementing job. Close collaboration between the operator and cementing service company was fundamental for the success of this job. Fluids selection, intensive software simulation, laboratory testing, proper execution, and final evaluation will be presented in this paper.
Achievement of 7-In. Production Liner Cementing with Seamless HP Zonal Isolation Integrity Whilst Coping with Challenges of Well Ballooning and Influx
Successfully achieving primary cementing objective within a very narrow pore-fracture pressure window is a significant challenge for the industry. During the cementing operation, variations in the equivalent circulation density (ECD) above or below the formation's pore/fracturing gradients can lead to wellbore losses or gains. An additional phenomenon that may be observed in these types of operations is wellbore ballooning, where wellbore fluids enter the formation under dynamic overbalance circulating conditions, and then flow back into the wellbore once pumps are stopped, dynamic circulating pressure is removed, and bottom hole pressure (BHP) is reduced, mimicking indications of a kick but without continuous influx of formation fluids. Designing a proper cement job to achieve zonal isolation and meet primary objective in such a scenario requires this challenge to be addressed and a fit-for-purpose solution to be developed to limit any post placement flowback that may compromise the cement integrity and zonal isolation. A 7-in. liner was run inside an 8 ½-in. open hole (OH) that had been drilled to section depth with a very tight drilling pressure window between gains from and losses to the formation. Losses and subsequent ballooning related flows were observed during the drilling phase. To determine the exact drilling window available, dynamic flow tests were conducted before the cement job to simulate ECD, and the available operational pressure window was identified between 13.4 - 14.6 lbm/gal. This data was used as input to a proprietary cementing software simulator to model the dynamic pressures expected during the cement job. Due to the small available window, conventional rules for density hierarchy, which keeps +/- 1.0 lbm/gal density difference among each fluid in cementing jobs, could not be followed. Also, due to the relatively small annular clearance, dynamic fluid friction pressures and optimization of liner stand-off played a critical factor in the job design. A high-pressure lightweight cement slurry was developed in the laboratory, aiming to withstand bottom hole formation pressure at 5,500 psi and achieve tight ECD control to minimize losses to the formation. The slurry system was optimized to be placed safely in the wellbore without jeopardizing the critical cement properties required for the annular isolation across the complete production liner. Multiple simulations and sensitivity tests were run to provide the optimized placement of the cement slurry and avoid losses or gains throughout cement placement. As even very small volumes of loss and subsequent flowback could contaminate the cement slurry, the density of the spacer ahead of the lead slurry was also optimized and enhanced through the inclusion of loss circulation materials, specifically engineered fibers, to further mitigate potential losses to larger fractures. The 7-in. liner cement job was conducted as planned with the liner rotated throughout the cement job to enhance the mud removal and improve cement bond. No losses or ballooning were observed throughout the entire cement job. Playback simulation showed the cementing job was executed as designed. formation integrity test (FIT) and cement bond log (CBL) confirmed shoe integrity up to 6,000 psi and zonal isolation requirement across the target formations. Proper planning and analysis of dynamic pressures and accurate operational control allowed us to achieve the objectives of this challenging cementing job. Close collaboration between the operator and cementing service company was fundamental for the success of this job. Fluids selection, intensive software simulation, laboratory testing, proper execution, and final evaluation will be presented in this paper.
Advanced Lightweight Thixotropic Cement Slurry (ALWTC) First Time Worldwide Application in a Primary Cementing Across Natural Fractured Limestones
Lost circulation while cementing intermediate sections across the Umm er Radhuma (UER) Formation, a naturally fractured limestone formation in UAE, is technically challenging and has financial impacts, including nonproductive time and remedial operational expenses. All fields in UAE encounter severe lost circulation while drilling UER Formation and cementing this section using lightweight slurries to isolate the zone and mitigate losses is a paramount task which requires several post-top jobs to provide zonal isolation of the casing. ALWTC technology was developed in the UAE as a lost circulation solution to reduce and mitigate losses across vugular and naturally fractured formations during drilling. But wells having the same or more complex loss scenarios during primary cementing where standard lost circulation materials and conventional lightweight slurries are used, have limitations. The ALWTC solution was evaluated and modified to be applied with the same lightweight technology currently used in primary cementing but enhanced with a specific thixotropic agent. An identified risk is the fast gel development (thixotropic behavior), a high risk that can compromise the cement placement in primary cementing, especially in jobs where large volumes are used. Smooth execution with well-coordinated events and best practices were deployed to ensure excellent execution without any health, safety, and environment or service quality incidents. During the first job, partial to full returns were observed, achieving cement to surface, which was our target. On one top job, only 5 to 6 bbl. of slurry were pumped, compared to 300 to 400 bbl. before. This saved 3 days of rig time and USD 25,000 of additional cost and services for the operator; additional jobs performed with similar performance. It was concluded that ALWTC is possible and suitable for primary cementing jobs across vugular and naturally fractured limestone formations. Cement evaluations also showed remarkable results across the UER and Simsima formations, compared to the normal slurry design that was being used before. ALWTC is a technology developed locally in the UAE for UAE cementing challenges across vugular and/or naturally fractured limestone formations. This technology has immense potential in the Middle East where losses across limestone formations are some of the biggest challenges and cementing to provide the required zonal isolation is a must.
Combined Engineered Lost Circulation Approaches for a Complex Fractured Carbonate Horizontal Formation: Middle East Case History
Lost circulation is a major challenge when drilling a well with depth reaching 8000 m in the horizontal section and a fractured carbonate reservoir as the target. High mud losses range from 34 m3/hr (210 bbl/hr) up to 120 m3/hr (750 bbl/hr). These losses reduce the rate of penetration and increase material costs, resulting in an increased overall well cost. In a worst-case scenario, immediate drilling problems can result, which include well control issues, formation pack off, and stuck pipe. Based on earlier drilling experience in one of middle east location, no single solution resulted in a high success rate, reducing losses, and regaining returns. The solutions involve decreasing the density, controlling the viscosity, and adding lost circulation materials (LCM) to the drilling fluid. These LCMs help to control the drilling parameters while offering mediocre aid with drilling plug placement. To address this severe lost circulation problem, a decision flow chart was constructed and combined with an engineered lost circulation approach to combat losses and strengthen the wellbore across these natural fractures. This approach was designed to more efficiently drill a new well in this field. Firstly, combined engineered wellbore strengthening approaches to cure losses included a high-strength, high-solid lost circulation system with a goal to control the losses. This system initially appeared efficient and was later combined with particulate material to improve strengthening and plugging capabilities. Due to fracture size uncertainty, an engineered fiber-based design loss circulation control pill was implemented to increase the sealing efficiency of the uncertain fractured zones. This pill was based on a resilient engineered fiber portion that used a particle size distribution principle. The concept of combining fibers and optimized solids was to form an impermeable grid to strengthen the wellbore integrity. A laboratory test was performed to confirm the system's ability to bridge the loss zone. These solutions were pumped through circulation ports above the drilling bottomhole assembly a total flow area (TFA) of 1.571 in.2. Once these solutions were incorporated, they helped to successfully regain fluid returns across the naturally fractured zones while permanently sealing the losses. Deploying the combined engineered pill and resilient engineered fiber pill at a different depth proved their applicability under different conditions and a standard engineering approach for improving wellbore integrity was developed for future drilling in this field. The aggregated solid grid formed by this combined approach ensured additional force and pressure created by drilling more deeply into the section and making it possible to successfully drill to the section TD without additional nonproductive time and risk of well control loss.
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