Description
Objective: The objective of this Phase I effort is to design and demonstrate the feasibility of a Sea-Based Recovery Station (SBRS) prototype capable of repurposing decommissioned offshore oil platforms into resilient landing pads for reusable launch-vehicle boosters. The solution should include structural modification approaches and analytical models capable of supporting the impact-load requirements of heavy-lift launch stages (current and next-generation heavy-lift launch stages). The resulting capability should enable scalable maritime recovery operations that support the Department of the Air Force's (DAF) objectives for Space Access and cost-effective launch sustainment. Description: This project seeks to enhance launch cadence and operational flexibility by exploring innovative maritime recovery options. Simultaneously, hundreds of offshore oil and gas platforms in federally controlled waters are reaching the end of their operational lifecycle. Traditional decommissioning and full-removal processes are capital-intensive, costing upwards of $1.6 billion per platform, and often cause significant disruption to established marine ecosystems. Project Able Baker seeks to address these challenges by developing a Sea-Based Recovery Station (SBRS) framework—a modular, resilient, and environmentally conscious solution that repurposes existing offshore infrastructure into landing pads for heavy-lift launch vehicles. This approach aims to provide the U.S. Space Force (USSF) and its commercial partners with a distributed network of recovery sites that enhance launch cadence, reduce sonic-boom exposure, and leverage existing maritime infrastructure to lower operational costs. The solution should be capable of: - Structural Engineering & Load Management: Designing reinforcement protocols to accommodate the specific plume, vibration, and high-intensity point-load dynamics of modern heavy-lift stages (e.g., Falcon 9, Vulcan, and New Glenn class). - Maritime Infrastructure Integration: Utilizing existing topside platforms for station-keeping, power, and logistics support to minimize the need for new construction. - Environmental & Ecosystem Preservation: Aligning with "Rigs-to-Reefs" precedents to ensure that the repurposing process preserves established artificial reef habitats; integrating continuous monitoring systems (e.g., pH, turbidity, and high-fidelity imaging) to ensure ecological health. - Advanced Safety & Operational Control: Implementing passive/active flame deflection, remote fire suppression systems, and precision navigation aids for autonomous landing guidance. - Rapid Turnaround Logistics: Establishing a framework for deck-framework for rapid deck-turnaround logistics, utilizing integrated barge or Vertical Takeoff and Landing (VTOL) systems to move boosters from the landing pad to transit vessels. - Regulatory & Strategic Alignment: Navigating the regulatory landscape for federal-waters operations to streamline permitting and avoid the catastrophic decommissioning costs associated with full platform removal. This topic seeks a robust framework that delivers structural resilience, cost-avoidance, and environmental stewardship. By repurposing legacy offshore assets, Project Able Baker will directly support the USSF's objective for Space Access while providing a scalable, sustainable model for future maritime launch recovery. Keywords: Sea-based recovery; offshore platform; reusable booster; rigs-to-reefs; sonic-boom mitigation; maritime logistics; digital twin; range integration CMMC Level: Level 2 (Self)