A Space Elevator for the Moon

1. A Space Elevator for the Moon Bradley C. Edwards, Ph.D. Black Line Ascension

2. Collaborators • This work is based on a NASA proposal developed in collaboration with: • Dr. Hyam Benaroya, Rutgers University • Dr. Michael Duke, Colorado School of Mines • Dr. Hermann Koelle, Berlin Technical University • Ms. Patricia Russell, NIAC • Dr. Bryan Laubscher, LANL • Ms. Pamela Luskin, Futron Corporation • Dr. David Raitt, ESA - ESTEC • Mr. Ben Shelef, Spaceward Foundation • Dr. Paul Spudis, JHU - APL

3. Basic Premise of Work (1) • We want to go to the moon in a real way

4. Basic Premise of Work (1) • We want to go to the moon in a real way …but does the public support lunar exploration (Wired)

5. Basic Premise of Work (2) • Launch is the single largest cost and complexity driver • $540M to $1B per launch • Congressional estimate of NASA program: $125B over 15 years • ~2000 tons to moon at $12k/lb

6. Rocket Transportation • Launch costs are expected to decrease <15% • Will improved operations and technology reduce costs further?

7. Current Moon Initiative (1) • Limited lunar presence • Not self-sustaining • Public, private, political support?

8. Current Moon Initiative (2) • Federally funded program • Relevant timelines: 4 pres. admins., 16 fed. budgets • No “business plan” with interesting ROI

9. A New Approach

10. The Major Difference • Utilize space elevator transport • Dramatic reduction in launch costs, complexity and risk • Immature but quickly developing technology • Enables large-scale self-sustained effort

11. The Space Elevator

13. 2006 SE Games

14. Rocket / SE Comparison

15. Direct Impact • Reduce program launch cost by ~$60B • Increase tons on moon from ~2000 to 18,000 • Reduces complexity • Reduces overall program risk

16. Rest of Program: Baseline • Mature landers based on Apollo • Overbuilt components • Redundant fuel depots in each orbit • Redundant modules in each orbit • Redundant resources

17. Rest of Program: Options • Large volume units • Excess capabilities enables use of new technology • Resale of excess launch capacity or lunar facilities • Same system for Mars

18. Complete System (1)

19. Complete System (2) • Flexible system • Resources everywhere

20. Summary of Concept • Mature systems / space elevator base lunar program. • • Lunar Base: Mature technology, extensive, redundant • • Space Elevators (2) • 3000 tons/yr @ $1B/yr operating cost • High reliability, safe, large envelop • Definable, up-front development risk • • Overall Program • Extensive lunar program: 69 ave. occupants • $68B (2005 - 2023) total • Safety : SE is safe and inexpensive allowing for redundant and overbuilt systems • - Sustainability:Good business case • - Expandable • - Limited development risk / low overall risk

21. Future Directions • SE-based lunar concept proposed to NASA • NASA not interested • Alternative options • Private • Establishing the components, finance and structure • Non-U.S. • Japan: presentation to the PM staff, general • Australia: multiple activities • Europe: EuroSpaceward, German SE games

22. Conclusion • A high return approach for a lunar base has been proposed. • The concept is not of interest to NASA • Alternative options for development exist