Nuclear Reactors for The Moon and Mars

1. Nuclear Reactors for The Moon and Mars Tyler Ellis Michael Short Martian Surface Reactor Group November 14, 2004

2. MSR Motivation

3. Nuclear Physics/Engineering 101

4. Nuclear Physics/Engineering 101

5. Habitat Reactor Proposed Mission Architecture

6. MSR Mission • Nuclear Power for the Martian Surface • Test on Lunar Surface • Design characteristics of MSR • Safe and Reliable • Light and Compact • Launchable and Accident Resistant • Environmentally Friendly

7. MSR Components • Core • Nuclear Components, Heat • Power Conversion Unit • Electricity, Heat Exchange • Radiator • Waste Heat Rejection • Shielding • Radiation Protection

8. CORE

9. Core - Design Concept • Develop a 100 kWe reactor with a 5 full-power-year lifetime • Evaluation of options were based on design criteria: • Low mass • Launchability • Safety • High Reliability

10. Core - Design Choices • Fast Spectrum • Ceramic Fuel – Uranium Nitride, 35 w/o enriched • Tantalum Burnable Poison • Liquid Lithium Heatpipe Coolant • Fuel Pin Elements in tricusp configuration • External control using drums • Zr3Si2 Reflector material • TaB2 Control material

11. Core - Design Specifications • UN fuel and Ta poison were chosen for heat transfer, neutronics performance, and limited corrosion • Heatpipes eliminate the need for pumps, have excellent heat transfer, and reduce system mass. • Li working fluid operates at high temperatures necessary for power conversion unit, 1800K

12. Fuel Pin Heatpipe Tricusp Material Core - Design Specifications (2) • Fuel pins are the same size as heatpipes and arranged in tricusp design

13. 99cm Reflector and Core Top-Down View Reflector Control Drum Reflector 37 cm Core Fuel Fuel Pin Zr3Si2 Reflector Total Mass: 1892kg 10cm Radial Reflector Core - Design Specifications (3) • Reflector controls neutron leakage • Control drums add little mass to the system and offer high reliability due to few moving parts

14. Core - Future Work • Perform U235 enrichment versus system mass analysis • Investigate further the feasibility of plate fuel element design • Develop comprehensive safety analysis for launch accidents

15. PCU

16. PCU – Design Concept Goals: • Remove thermal energy from the core • Produce at least 100kWe • Deliver remaining thermal energy to the radiator Components: • Heat Removal from Core • Power Conversion System • Power Transmission System • Heat Exchanger/Interface with Radiator

17. PCU – Design Choices • Heat Transfer from Core • Heat Pipes • Power Conversion System • Cesium Thermionics • Power Transmission • DC-to-AC conversion • OOOO gauge Cu wire transmission • Heat Exchanger to Radiator • Annular Heat Pipes

18. PCU – Design Specifications • Heat Pipes from Core: • 1 meter long • 1 cm diameter • 100 heat pipes • Molybdenum Pipes • Lithium Fluid • Boiling point @ STP: 1615K • Pressurized to boil @ 1800K CORE

19. PCU - Design Specifications (2) • Thermionic Power Conversion Unit • Mass: 250 kg • Efficiency: 10%+ • 1MWt -> 100kWe • Power density: 10W/cm2 • Surface area per heat pipe: 100 cm2

20. Reactor PCU - Design Specifications (3) • Power Transmission • D-to-A converter: • 20 x 5000VA units • 300kg total • Small • Transmission Lines: • AC transmission • OOOO gauge Cu wire • 1kg/m

21. PCU - Decision Specifications (4) • Heat Pipe Heat Exchanger

22. PCU – Future Work • Improving Thermionic Efficiency • Material behavior in high radiation environment • Heat pipe failure analysis • Scalability to 200kWe • Using ISRU as thermal heat sink

23. Radiator

24. Radiator – Design Concept • Need a radiator to dissipate excess heat from a nuclear power plant located on the surface of the Moon or Mars.

25. Radiator – Design Choices • Evolved from previous designs for space fission systems: • SNAP-2/10A • SAFE-400 • SP-100 • Transfers heat from PCU to heat pipes • Radiates thermal energy into space via large panels

26. Radiator – Design Choices (2) • Heat pipes send heat to large radiator panels through vaporization of fluid • Heat conducted to panels at the condensing end of the heat pipes • High-emissivity panels use radiation to reject heat to space

27. Radiator – Design Specifications • Nb-Zr heat pipes with carbon radiator panels • Panels folded vertically next to reactor during transit • For operation panels lay parallel to surface Core PCU Unfolds on surface Panels radiate to environment Radiator Packed for launch

28. Radiator - Future Work • Mechanical design of radiator panels • Mathematical modeling

29. Shielding

30. Shielding - Design Concept • Dose rate on Moon & Mars is ~14 times higher than on Earth • Goal: • Reduce dose rate to between 0.6 - 5.7 mrem/hr • Neutrons and gamma rays emitted, requiring two different modes of attenuation

31. Shielding - Design Choices Neutron shielding Gamma shielding B4C shell Tungsten shadow shield • Separate reactor from habitat • Dose rate decreases as 1/r2 for r >> 50cm • Use lunar or Martian surface material for further radiation attenuation

32. Shielding - Constraints • Weight limited by landing module (~3 MT) • Temperature limited by material properties (1800K) Courtesy of Jet Propulsion Laboratory

33. Shielding - Geometry • Cylindrical shell to attenuate neutrons to target dose within < 50 m • Shadow shield may be more appropriate depending on mission parameters • B4C will be stable up to 2100K • Hydrogenous materials are not viable

34. Shielding - Future Work • Shielding using extraterrestrial surface material: • On moon, select craters that are navigable and of appropriate size • Incorporate precision landing capability • On Mars, specify a burial technique as craters are less prevalent • Specify geometry dependent upon mission parameters • Shielding modularity, adaptability, etc.

35. Reactor Mass Breakdown Core: 2.7 MT PCU: 2.05 MT Radiator: 1.5MT Shield: 2 MT ___________________ Total Mass of Reactor – 8.25 Metric Tons Well Below Lander Limit of 15 MT

36. MSR GroupExpanding Frontiers with Nuclear TechnologyTyler Ellis tyler9@mit.eduMichael Short hereiam@mit.edu