Nuclear electric propulsion systems provide a variety of benefits including increased science payload, reduced flight times and longer mission lifetimes. These advantages enable a wide range of missions such as manned missions to Mars, unmanned missions to the outer planets and deep-space. The thermal management system linking the reactor to the hot end of the power conversion system must be efficient, lightweight and reliable. These requirements become more challenging as the total power scales to the megawatt level. The Phase I program included successful demonstration of high-power heat pipes and the development of a reactor design. In this Phase II SBIR program, Advanced Cooling Technologies will lead the development and maturation of a highly reliable, efficient, and lightweight heat pipe-based thermal management system for the hot end of the power generation system for nuclear electric propulsion. High-power heat pipes will be used be used to transport thermal energy, at the megawatt scale, to the hot end of the power conversion unit. The proposed system is passive and highly reliable with built-in redundancy. Anticipated
Benefits: The thermal management technology proposed here is relevant to several areas of NASAs Technology Roadmap, including Power for In-Space Propulsion, Fission Space Power and Energy Storage and Heat Transport for Thermal Control Systems. The system will benefit many space-based fission power systems such as nuclear electric propulsion and power generation on the lunar and Martian surface. The proposed system is capable of transporting a significant amount of thermal energy from a nuclear reactor to a power conversion system. In addition to space-based applications, the thermal management system is relevant to small modular and micro nuclear reactors. Small reactors have several advantages including reduced capital investment, reduced construction time and scalability.
