Offshore wind power involves generating electricity from wind farms located at sea. Because wind speeds are generally higher offshore than on land, these farms produce more electricity for the same amount of installed capacity. Both wind and solar energy are renewable and do not emit carbon, which helps reduce dependence on fossil fuels such as oil and gas. The papers synopsized in this year’s Offshore Facilities feature cover a breadth of related subjects that will be critical to the future of the industry.
Automation in the offshore oil and gas industry makes production safer, faster, and more efficient. It reduces human error, improves quality control, and allows real-time monitoring of operations.
Machine learning improves offshore industries by enhancing safety, efficiency, and sustainability. It tracks and predicts environmental changes, such as oil spills or marine life patterns, aiding in better environmental management and response.
Remotely operated vehicles are used in offshore operations to inspect, maintain, and repair underwater infrastructure; the offshore industry uses 3D video imaging technology to provide detailed real-time images of the underwater environment.
Corrosion in offshore environments occurs because of factors such as seawater, sea salts, temperature, salinity, and moisture. It is crucial to monitor corrosion because it can lead to major structural failures.
Hydrogen can be produced offshore using renewable energy sources such as wind and solar, which do not emit greenhouse gases and help combat climate change.
Supply-chain logistics boost efficiency by cutting costs, removing unnecessary steps, and speeding up product delivery. An efficient supply chain can lead to higher revenue, lower operational costs, and better overall performance.
Decommissioning is the final stage of an oil or gas project and involves significant technical, economic, social, and environmental challenges. It is a lengthy, costly, and complex process that must be carefully planned and managed to avoid serious problems. Several ideas have come to the surface that show innovative ways to repurpose a decommissioned platform or ways to cut the cost of decommissioning.
This Month’s Technical Papers
Shear-Wave Velocity Data Assists Modeling for Offshore Windfarm Development
Robotic Technology Enables Automated Nondestructive Weld Inspection in Subsea Zone
Study Finds Compact Carbon-Capture Modules Feasible on Offshore Production Facilities
Recommended Additional Reading
SPE 217706 Dynamic Simulation of Riser-Gas Handling With a Fixed-Choke Constant Outflow by Zhaoguang Yuan, SLB, et al.
OTC 35092 Reducing Carbon Footprint by Using Fiber‑Reinforced Polymers in FPSOs by S. Eves, NOV, et al.
OTC 35393 Challenges and Approaches to Solutions for Green Decommissioning and Recycling of Offshore Facilities by Carlos Alberto Machado, American Bureau of Shipping, et al.
Avinash Karre, SPE, is a principal process engineer at Worley. He holds an MS degree in chemical engineering and has 17 years of industrial experience. Karre’s research interests are processing design, catalyst optimization and development, developing catalyst technologies, separation, reservoir simulation, flow assurance, water management, and carbon capture. He has volunteered on SPE Award committees and served as chairperson for the Projects, Facilities, and Construction Subcommittee of SPE’s Annual Technical Conference and Exhibition.