We will demonstrate the feasibility and commercial applicability of a novel energy harvesting system that converts thermal energy from air-sea temperature differences into electricity. This capability will extend the endurance and capability of NOAA observing platforms, reduce lithium battery waste, increase human and environmental safety, and support efforts to detect and monitor critical trends particularly in remote, high-latitude regions. Air-sea temperature contrasts can be exploited using an Organic Rankine Cycle, a thermodynamic process commonly used for industrial waste heat recovery. The proposed thermal engine will be optimized for the small temperature differentials encountered in the maritime environment and scaled for the unique needs and constraints of NOAA observational platforms. The system is compact, low-maintenance and capable of long-term deployment on a fixed platform, buoy, or ice floe -- or on a mobile platform such as a drifting buoy or autonomous surface vehicle.Potential markets include governmental organizations tasked with environmental stewardship (e.g. NOAA, EPA, USGS, NASA), transportation safety and natural resource management (e.g. USCG, FAA, BOEM) and national security (DOD, DHS). Improved observing system capabilities facilitated by this development will also be of interest to the private sector in the oil and gas, defense, and telecommunications industries.SUMMARY OF
Anticipated Results: This effort will result in proof-of-concept validation of a novel clean energy source that could fundamentally alter the logistics and economics of NOAA observing system operations. We will demonstrate, via numerical simulation and laboratory experimentation, the ability of the proposed system to generate electricity from air-sea temperature differences. We will define leading use cases and evaluate the public- and private-sector market potential.
