Chad Kessens, Ryan McDaniel, Melahn Parker, Shane Ross, Luke Voss The Next Giant Leap.

Slides:

Advertisements

Similar presentations

Chapter 17 Earth in Space Vocabulary.

Advertisements

Detail actions necessary to implement the interim housing mission in the post-disaster environment Identify command and control structures at all levels.

Terex Cranes Steve Filipov, President Developing Markets and Strategic Accounts.

National Aeronautics and Space Administration Presentation to the NASA Goddard Academy 2. Constellation Overview Ken Davidian Lead, Commercial.

Meeting the Goal: Progress Report Washington, DC June 30, x’25 National Summit 2010: Mission Achievable.

Unleashing Innovation Dawn Rittenhouse Director, Sustainable Development.

Steven Jay Mueller, President International WoodFuels

Resource and Energy.

Announcements Pick up graded homework. Pick up handout (“The Virtual Astronaut”) and read over the weekend. First project due today by 5:00 p.m.

NASA_G_O_02_09_05.ppt 1 National Goals and Objectives National Goal To advance U.S. scientific, security, and economic interests through a robust space.

ANKIT KUMAR B.TECH(ECE) 4 th sem roll Wireless Power Transmission.

China’s Sustainable Energy Policy

Arguments Against Nuclear Power Development in Iran May, 2003.

RUBY REVELES PERIOD 3 4/14/11 Solar & Nuclear Energy.

Space Exploration: Should It Be Done? Nishith Patel.

The experience of Acciona in collaborative R&D: building and sharing knowledge for effective open innovation.

Helium-3: The Future Energy Source? Major Wayne Wisneski.

PRESENTATION. INDUSTRIAL International Clients demand response and construction efficiency and are looking to review their business investments to give.

Dr. Fatih Birol Chief Economist Head, Economic Analysis Division International Energy Agency / OECD WORLD ENERGY INVESTMENT OUTLOOK.

ACHIEVING SUSTAINABILITY Unit 3-2a Understanding Energy.

MANITOBA CEEN 590 Energy Policy. YES TO OIL PIPELINES REASONS They will bring economic benefits and create new jobs. e.g. the Energy East Pipeline Project.

The SME Instrument in HORIZON 2020

How Rising Energy Prices Can Affect Your Portfolio Common Sense on Complex Issues.

Delivering Power & Water Efficiently

1 CITY DEVELOPMENT WORLD AFRICA 2006 Johannesburg, South Africa November 6-9, 2006 TEAMWORK: WHY METROPOLITAN ECONOMIC STRATEGY IS THE KEY TO GENERATING.

Jobs in a Green Economy Rebuilding for a Low Carbon Future Bracken Hendricks, Senior Fellow Baltimore MD (07/21/09) Governor’s Workforce Investment Board.

Laser Propulsion and Space Based Solar Power Keith Henson (L5 Society Founder)

Wireless Power Transmission for Solar Power Satellites By B.Ravindra Reddy (MT097109)

The ISECG Global Exploration Roadmap Status update at Target NEO2 Workshop July 9, 2013 NASA/Kathy Laurini Human Exploration & Ops Mission Directorate.

Spirit of Houston Past 372,207 vehicles Oct ’14.

TOPIC 3.2 ENSURING ADEQUATED WATER RESOURCES AND STORAGE INFRASTRUCTURE TO MEET AGRICULTURAL, ENERGY AND URBAN NEEDS.

Tomorrow’s Energy Finding Renewable Alternatives to Supplement the Current Infrastructure Wind is one of the many resources available for producing sustainable.

Advanced Space Exploration LEO Propellant Depot: Space Transportation Impedance Matching Space Access 2010 April 8-10, 2010 Dallas Bienhoff Manager, In-Space.

Presented to Kepler Pre-Launch Educator Workshop January 31, 2009 Shari Asplund Discovery and New Frontiers Programs Education and Public Outreach Manager.

MIT : NED : Mission to Mars Presentation of proposed mission plan

Minimalist Mars Mission Establishing a Human Toehold on the Red Planet Executive Summary DevelopSpace MinMars Team.

Mars Today 1 An immediate and inexpensive program for manned Mars visitation.

Construction of an International Space Vehicle Using the Space Station Dan Roukos ASTE 527 December 15, 2009.

Nuclear Energy and Waste By: David Long ( ); Chris Marcyniuk ( ); Adam Foster ( ) IMS3 Sustainability.

Blunting the peak – oil sands supply and peak oil Mike Ashar Executive Vice President Suncor Energy Association for the Study of Peak Oil and Gas Denver.

Contemporary Engineering Economics, 6 th edition Park Copyright © 2016 by Pearson Education, Inc. All Rights Reserved Engineering Economic Decisions Lecture.

Phases of the Moon and Eclipses LunarPhasesanhdEclipseAnimate.ppt.

Some Slides from the Space Studies Institute

INTRODUCTION Now-a-days we are using the solar power to generate electricity by the solar panels mounted on the earth. In outer space, the sun always.

Energy and Food Production CENV 110. Energy intensity of food production Crops Land animals Fish.

 Solar Energy is renewable energy that is powered by the sun.  Solar energy can be converted into other forms, such as heat and electricity.

QTYUIOP THERMIONIC SPACE POWER THE EMERGING SOURCE OF SPACE POWER IN THE NEXT DECADE AUBURN UNIVERSITY AUGUST 17, 1999.

ASTEROID MINING S. SYED MOHAMED RAFEEK, , CEG, ANNA UNIVERSITY, CHENNAI.

Space Power Satellites & Microwave Power Transmission

PRANEETH DHANRAJ. CONTENTS INTRODUCTION SOLAR POWER SATELLITE DC TO MICROWAVE GENERATION RECTENNA DEVELOPMENT OF FUNCTIONAL SYSTEM MODEL FOR SPS SPACE.

Jeopardy $100 $200 $300 $400 $500 Vocabulary $100 $200 $300 $400 $500 Name that Region $100 $200 $300 $400 $500 Where is my home? $100 $200 $300 $400 $500.

National Goals and Objectives

The Future of Human Spaceflight *** A Journey to Mars

3D Printing in Space.

Space Tug Propellant Options AIAA 2016-vvvv

THE SOLAR SYSTEM by Hunter

Opportunities in the Changing Energy System

Earth’s human population continues to grow.

Asteroid Mining 27 October 2017.

Eclipses Occur when the shadow of one object blocks the view of another object Two types: Solar Lunar.

SOL Review The Moon.

bellringer Add questions and summary to Community Ecology Notes

It is the best time to invest these stocks

affected by human needs and wants?

Comparison of Nonrenewable Energy Fuels

Deep Space Exploration Requires the best from all of us

Mineral Resources Section 7.1

Can not perform complicated experiments (Wanda)

Dr. James Vedda Center for Space Policy and Strategy

Space Florida Enabling the Future of Space Commerce

Presentation transcript:

Chad Kessens, Ryan McDaniel, Melahn Parker, Shane Ross, Luke Voss The Next Giant Leap

28 May Heliopolis Mission To build a profitable, self-sustaining foothold for humanity in space

28 May Heliopolis: Space Business Park / Community Support several industries Solar power satellites (SPS)* Communications satellites Zero-gravity manufacturing Tourism Asteroid mining Capacity for growth (self- replication) Lunar L1 halo orbit Continuous sunlight Moon-viewing for tourists Necessary for future space infrastructure *Only revenue from SPS modeled

28 May a Heliopolis Development Timeline Research and Development begins First launch Heliopolis construction begins; Lunar Mass Driver operational Permanent Heliopolis habitation begins Launch Asteroid retrieval mission Asteroid arrives at Heliopolis Heliopolis construction complete Accounting Profit Economic Profit PHASES:

28 May Phase 0 ( ) Shanty Town Construction ISS-like modules to L1 Mass driver to Moon 3-month crew rotations Cost: 35 B$ (Y2K) People: Shanty Town (Earth- Moon L1) Moon Resources Sun Energy Earth People and Resources

28 May Phase 1 ( ) Begin Construction of Heliopolis Build first permanent habitation modules Construction materials from Moon 3-month crew rotations Cost: 27 B$ People: % complete Heliopolis Moon Sun Earth

28 May Intermediate Construction Stage Permanent habitation Manufacture of SPSs/Commsats Launch asteroid retriever Cost: 151 B$ Revenue: 343 B$ People: % complete Phase 2 ( ) Heliopolis Moon Asteroid Sun GEO Products Earth

28 May Phase 3 ( ) Final Construction Stage Asteroid returned Heliopolis essentially self-sufficient Cost: 50 B$ Revenue: 850 B$ People: % complete Heliopolis Moon Asteroid Sun GEO Earth

28 May Phase 4 (2039+) Heliopolis Completed Normal operations Cost: 0.19 B$ per year Revenue: 214 B$ first year People: % complete Heliopolis Moon Asteroid Sun GEO Earth

28 May Infrastructure Requirements Module fabrication facility Heavy-lift launch vehicle (HLLV) services Lunar mass driver Inter-orbital shuttle Ground receiver arrays (rectennas)

28 May Technology Requirements Enabling Technology 250-tonne-to-LEO class HLLV Improved automation Nuclear reactor in space Closed-loop recycling Enhancing Technology SEP using O2 Nuclear thermal propulsion Improved PowerSail efficiency Mass driver propulsion

28 May Cash Flow Analysis (log scale) Chad $Y2K

28 May Alaska Pipeline Comparison Alaska Pipeline Heliopolis Cost before revenue 22.7 B$105 B$ Time to revenue2.21 years15 years Avg. cost per year before revenue 10.3 B$7 B$ Avg. profit per year 3 B$214 B$ 1 Energy supplied per year MBTUs delivered 233 MBTUs produced 1 1 Beginning of Phase 4 2 World demand of 612 QBTUs in 2020

28 May Three Gorges Dam Comparison Three Gorges Dam Heliopolis Cost before revenue 26.6 B$105 B$ Time to revenue20 years15 years Avg. cost per year before revenue 1.33 B$7 B$ Avg. profit per year62.8 B$ B$ 1 Energy supplied per year MBTUs delivered 233 MBTUs produced 1 1 Beginning of Phase 4 2 World demand of 612 QBTUs in Revenue; profit figures unavailable

28 May Environmental Impact Alaska Pipeline Three Gorges Dam Nuclear PowerHeliopolis 12 M gallons of oil spilled over last 25 years Toxic levels of arsenic, mercury, lead, cyanide in water supply; 1.9 million people displaced Chernobyl affected 7 million, contaminated 155,000 sq.km 1 Construction of rectennas (but still allows use of land); microwaves not harmful 2 1 Belarussian Embassy website Stanford study

28 May Conclusions (1 of 3) O`Neill was right: world market exists to begin supply of solar energy World demand of 612 QBTUs 1 far exceeds world production capability of 496 QBTUs 2 SPS production can begin to supply unmet demand Solar energy from SPS cleaner, safer than alternatives No risk of toxic wastes/spills No risk of explosions or meltdowns No people displaced, no land made unusable 1 US DoE 2 International Energy Agency

28 May Conclusions (2 of 3) LSMD study comparable to 1975 Stanford study Differences reflect 25 years of technological advances However: LSMD study represents fundamentally new analysis Integrated cost model demonstrates project`s economic feasibility Technology exists or can be designed to begin project in the next 20 years

28 May Conclusions (3 of 3) Economic profit returned in 20 years Positive cash flow in 15 years Initial investment of $105 billion Self-sufficiency and internalizing costs critical to project success Power requirements dominated by industrial refinery needs Project cost driven by food production Low mass, but biomass only available from Earth Personnel costs surprisingly insignificant