ESSS O&G’s Post

𝗖𝗼𝗻𝘀𝗶𝘀𝘁𝗲𝗻𝗰𝘆 𝘁𝗵𝗿𝗼𝘂𝗴𝗵 𝗮𝘂𝘁𝗼𝗺𝗮𝘁𝗶𝗼𝗻 𝗶𝘀 𝗮𝗰𝘁𝗶𝘃𝗲𝗹𝘆 𝗿𝗲𝗱𝗲𝗳𝗶𝗻𝗶𝗻𝗴 𝘁𝗵𝗲 𝗼𝗶𝗹 𝗮𝗻𝗱 𝗴𝗮𝘀 𝗱𝗿𝗶𝗹𝗹𝗶𝗻𝗴 𝗽𝗿𝗼𝗰𝗲𝘀𝘀. H&P's Sonny Auld, Fergus Hopwood, Zack Whitlow, Marc Willerth, and Sarah Kern highlight several case studies displaying the value of the pursuit of consistency in this week's Tech Paper Tuesday manuscript, presented at this year's International Association of Drilling Contractors / Society of Petroleum Engineers International Drilling Conference & Exhibition. As the industry continues to embrace automation technologies, we can expect even greater advances, transforming tomorrow's world of energy production for the better, as we redefine roles in drilling operations for future generations!

Managed Pressure Drilling (MPD) MPD is a drilling technique used in the oil and gas industry to control well pressure during drilling operations. Involves the precise management of drilling fluid properties, flow rates and counterpressure to optimize drilling performance and mitigate drilling challenges such as well instability, loss of circulation and formation damage. MPD techniques allow drilling engineers to accurately control and manipulate the pressure profile in the well, which can help improve drilling efficiency, increase safety, and reduce non-productive downtime. MPD can be done using various methods and equipment, such as specialized drilling platforms, surface counterpressure control, bottom-well mud gas separation, and advanced drilling fluid systems. MPD is commonly used in challenging drilling scenarios such as high pressure/high temperature (HP/HT) wells, depleted reservoirs, and areas with narrow pressure margins. Overall, MPD is a technology used in the oil and gas industry to optimize drilling operations and improve well integrity by carefully managing the pressure dynamics during the drilling process. Managed Pressure Drilling (MPD) is an important technique in the oil and gas industry for several reasons: Improved Drilling Efficiency: The MPD allows drilling engineers to accurately manage and control well pressure, which can help optimize the drilling process. By maintaining the correct pressure profile, MPD can help mitigate drilling challenges, such as well instability, loss of circulation, and formation damage, leading to increased drilling efficiency and reducing non-productive time. Enhanced Security: MPD techniques can contribute to increased safety during drilling operations. By closely managing well pressure, MPD can help prevent kicks (uncontrolled influx of training fluid) and explosions (uncontrolled release of reservoir fluid to the surface), which are critical safety risks in drilling operations. The MPD also allows for better control of well pressure during connections and travel, reducing the risk of well check incidents. Extended Drilling Capability: MPD can allow drilling operations in challenging environments, where traditional drilling methods can be limited. For example, in high-pressure/high-temperature (HP/HT) wells or depleted reservoirs, MPD can help manage well pressure and optimize drilling performance, allowing for extended drilling ability and accessing previously challenging reserves. Reduced Environmental Impact Economics of cost Overall, Managed Pressure Drilling (MPD) is an important technology in the oil and gas industry that can help to improve drilling efficiency, increase safety, extend drilling capacity, reduce environmental impact and potential cost saving, making it a valuable technique for the modern drilling operations. #petrounlocked

Effective drilling scheduling is crucial to operator and contractor success. Even with modern scheduling software, organising drilling operations is a complex and critical process which can often have substantial economic ramifications. Since a major contributor to deferred production and unplanned NPT in drilling operations is related to the frequent occurrence of BHA blockage and damage, preventing these debris-related problems is crucial to optimising the drilling process. Maintaining necessary efficiency in the face of the unpredictable realities of the drilling environment, leaves no room for error without financial and reputational consequences. The Sentry Sub™ uses high-quality materials and smart design to filter and prevent debris-related delays. With the highest capacity of any tool on the market, the Sentry Sub ™ captures and retains large quantitates of general debris to protect your BHA and allow your drilling programme to run smoothly. An exclusive benefit of utilising the Sentry Sub™ is the additional collection of ferrous material which prevents magnetic interference with the measurement tools in the drill string. This of course prevents the correlating postponement which occurs with magnetic fines. The Sentry Sub™ ’s innovative, built-in bypass system additionally ensures that drilling adheres to schedule as the technology prevents unnecessary trips by allowing the drilling process to continue even if maximum capacity is reached. To learn more about the features and benefits of the Sentry Sub™ click here: https://lnkd.in/eSJwBux6

HOW DOES Axcel OPTIMIZE DRILLING COSTS ? https://axcel.webnode.ro/ Axcel optimizes drilling costs by utilizing advanced technologies to enhance operational efficiency and decision-making. Here’s how Axcel contributes to cost optimization in drilling operations: 1. Precision Drilling: Enhanced Decision-Making: Axcel uses AI algorithms to analyze geological data, enabling precise decision-making about drilling parameters such as depth, angle, and speed. This reduces the chances of errors that could lead to costly mistakes. Risk Mitigation: By identifying potential risks early, Axcel helps in planning effective mitigation strategies, reducing the likelihood of accidents that could result in financial losses. 2. Efficient Resource Utilization: Optimized Resource Allocation: Axcel's predictive capabilities allow for better allocation of resources, such as manpower and equipment, ensuring they are used efficiently and effectively. Reduced Downtime: By anticipating and addressing potential issues before they escalate, Axcel minimizes downtime, which is a significant cost factor in drilling operations. 3. Cost-Effective Operations: Energy Management: Axcel optimizes energy use by adjusting drilling parameters to minimize energy consumption without compromising performance, leading to cost savings in energy expenditures. Inventory Management: By providing insights into equipment and material needs based on predictive maintenance and real-time monitoring, Axcel helps in maintaining an optimal inventory level, avoiding both overstocking and shortages. 4. Process Automation: Streamlined Operations: Automation of routine tasks through Axcel reduces the need for manual intervention, lowering labor costs and reducing the potential for human error. Real-Time Adjustments(if applied): Automated real-time adjustments to drilling parameters ensure optimal operation conditions are maintained, reducing the wear and tear on equipment and extending their lifespan. 5. Data-Driven Maintenance: Predictive Maintenance: Axcel predicts equipment failures before they happen, allowing for timely maintenance that prevents costly breakdowns and extends the life of drilling equipment. Maintenance Scheduling: By analyzing usage patterns and operational data, Axcel schedules maintenance at optimal times, minimizing disruptions and maintenance costs. 6. Compliance and Safety: Regulatory Compliance: By ensuring that all operations are within regulatory guidelines, Axcel avoids fines and penalties that can arise from non-compliance. Safety Enhancements: By reducing the risk of accidents through better risk management and predictive analytics, Axcel lowers the potential costs associated with workplace injuries and incidents. So : Axcel optimizes drilling costs through a comprehensive approach that integrates advanced AI-driven decision-making, resource management, and automation. This results in more efficient and effective operations, reduced downtime, and lower overall costs.

Drilling Motors (PDM) in the Oil Industry: Innovation and Precision Drilling motors are a key technology in directional drilling within the oil industry. Also known as Positive Displacement Motors (PDM), these devices allow for more efficient well drilling, improving directional control and drilling speed. How Drilling Motors Work A drilling motor works by harnessing the hydraulic energy from the drilling fluid (mud) circulating through the system. As the mud passes through the motor, it drives the rotor, which rotates inside the stator, generating mechanical movement that powers the drill bit. This allows for drilling without relying on the surface rotary system, providing greater control over the drilling direction. Main Components 1. Rotor and Stator: The heart of the motor, where the interaction between both produces rotational movement. 2. Housing: Protects the internal components and supports axial and torsional loads. 3. Power Section: Converts fluid energy into torque to drive the drill bit. Applications in Directional Drilling Drilling motors are essential for drilling wells with challenging trajectories, such as horizontal wells and wells with sharp curves. Their ability to rotate the drill bit without having to rotate the entire drill string reduces equipment wear and increases the precision of well trajectory control. Operational Advantages - Better Directional Control: Motors enable deviating the well to precise angles, optimizing drilling in productive zones. - Cost Reduction: By improving efficiency and reducing drilling time, motors contribute to lowering operational costs. - Drilling in Complex Formations: They are effective in formations where conventional drilling techniques are not feasible or efficient. Technological Advancements In recent years, drilling motors have evolved with innovations such as: - High-Torque Motors: Designed to deliver greater power in challenging wells. - Improvements in Stator Elastomers: For increased durability under extreme conditions. - Long-Life Motors: Optimized for durability and reduced maintenance times. Conclusion Drilling motors are a crucial tool in optimizing oil and gas operations, particularly in complex drilling scenarios. Their proper use enhances control, reduces time and costs, and increases operational safety. With the continuous evolution of this technology, PDMs will remain a vital part of the future of directional drilling.

Remote monitoring of drilling operations involves real-time data collection and analysis during drilling processes. By leveraging advanced technology, it enables remote decision-making, enhances safety, and optimizes drilling operations. Without a doubt one of the jobs that I most enjoy doing, demanding but rewarding.

MPD Managed Pressure Drilling (MPD) is a drilling technique used in the oil and gas industry to control well pressure during drilling operations. Involves the precise management of drilling fluid properties, flow rates and counterpressure to optimize drilling performance and mitigate drilling challenges such as well instability, loss of circulation and formation damage. MPD techniques allow drilling engineers to accurately control and manipulate the pressure profile in the well, which can help improve drilling efficiency, increase safety, and reduce non-productive downtime. MPD can be done using various methods and equipment, such as specialized drilling platforms, surface counterpressure control, bottom-well mud gas separation, and advanced drilling fluid systems.

MPD Managed Pressure Drilling (MPD) is a drilling technique used in the oil and gas industry to control well pressure during drilling operations. Involves the precise management of drilling fluid properties, flow rates and counterpressure to optimize drilling performance and mitigate drilling challenges such as well instability, loss of circulation and formation damage. MPD techniques allow drilling engineers to accurately control and manipulate the pressure profile in the well, which can help improve drilling efficiency, increase safety, and reduce non-productive downtime. MPD can be done using various methods and equipment, such as specialized drilling platforms, surface counterpressure control, bottom-well mud gas separation, and advanced drilling fluid systems.

Ready to revolutionize your drilling operations? Imagine #simulating drilling processes in a precise virtual environment, analyzing real-time data, and boosting your team’s efficiency like never before. With 19 advanced simulation programs, you can now access the tools that will drive safety, cut costs, and enhance decision-making. Whether offshore or onshore, these solutions are transforming how drilling decisions are made. Don’t miss out—explore the technologies that will lead you into the future of drilling operations! Here’s a closer look at the top simulation programs that are changing the industry: 1.#OpenLab: Offers realistic simulation integrated with Ullrigg test site for advanced training and operations. 2.#DrillSim Series: Flexible and scalable, designed for well control and in-depth drilling scenarios. 3.#DS5000: A premium solution for complex drilling processes with real-time data analysis. 4.SLBWellSimTech: Specializes in well control simulations for deep drilling scenarios. 5.#iDrillSim: Simple and mobile-friendly, perfect for introductory training. 6.#Virtual Rig (NOV): Offers an immersive 3D training environment for crew operations. 7.#GE’s Cyberbase: Uses digital twin technology for realistic simulations of full rig operations. 8.Simtronics: Focuses on realistic control room training for drilling teams. 9.#Kongsberg Drilling Simulator: Advanced tool for safety and operational training. 10.Weatherford RigSENSE: Real-time monitoring and data analysis for optimizing drilling operations. 11.Oliasoft WellDesign: Provides engineering solutions for well design and simulation. 12.Interwell Simulation: Advanced simulation tool for optimizing drilling performance and control. 13.eDrilling : Simulates advanced drilling systems for better performance in challenging environments. 14.#Petrofac Training Simulator: Safety-focused training for drilling and operations. 15.NExT SLB Drilling Simulator (Schlumberger): Enhances skills for drilling personnel with real-time training scenarios. 16.Pason RigSite: Data-driven simulation to improve decision-making on drilling operations. 17.DOF Simulator: Focuses on deepwater drilling simulation for offshore environments. 18.#Cyberbase Simulator: Uses digital twin technology to replicate drilling operations. 19.#DrillMap: Ideal for planning, analyzing, and optimizing drilling processes with advanced simulation features. Each of these tools is designed to enhance safety, efficiency, and productivity in the highly complex world of drilling. Explore which one suits your needs, and elevate your operations to new heights! #OpenLab #Ullrigg SLB Aker BP ASA #DrillSim #DS5000 WellSimTech #iDrillSim #VirtualRig #NOV #GE #Cyberbase Simtronics KONGSBERG Weatherford #RigSENSE Oliasoft Interwell eDrilling Petrofac (Malaysia-PM304) Limited NExT SLB Pason DOF #DrillMap ExxonMobil Chevron TotalEnergies bp ADNOC Group aramco Maersk Drilling Transocean Schneider Electric Hub Siemens Energy Equinor #Simulation