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Status of International Space Station

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Status of International Space Station NASA and the International Space Station Sam Scimemi Director, International Space Station HEO NAC Human Exploration and Operations Kennedy Space Center NASA Headquarters December 10, 2013 The Internaonal Space Staon is essen+al to mee+ng the Naon’s goals in space Returning benefits to humanity through research Enabling a self-sustaining commercial LEO market Laying the foundaon for long-duraon spaceflight beyond LEO Leading the world in an exploraon partnership 2 3 “Time works so hard for us, if only we can let it.” Tana French Time to complete a study in orbit – 2 weeks to 5+ years Time from comple+on of study in orbit to first publicaon – 1 to 3 years for majority of inves+gaons Time from publicaon or patent to product being in the marketplace – 3 to 20 years (shorter for technologies, longer for drug development) 4 Historical Micro-G Research Perspec+ve Exploratory Survey Applicaon 1994-1998 1998 2011 1973-1979 1981-2011 Assembly Complete ~1.5 years of produc+ve on-orbit micro-g research M. Uhran, Posi+oning the ISS for the U+lizaon Era 5 Some of the Benefits to Humanity To-date • Discoveries – Cool flames vaporize without visible flame in space (Combustion and Flame) – Human immune cells adapt to weightlessness (J. Leukocyte Biology) – MAXI black hole swallowing star (Nature) – Vision impacts and intracranial pressure (Opthalmology) – Microbial virulence (Proc. Nat. Acad. Sci.) • Technology Spinoffs – NeuroArm image-guided robot for neurosurgery translates Canadarm • Results with poten2al human benefits technology to the operation room – Amgen bone loss drug testing aided by ISS – Dusty plasmas applications for medical mouse research model applications and neutralizing drug-resistant – Hyperspectral imaging for environmental bacteria monitoring – “Smart” fluids (colloids) phase transi+on – YouTube Space Lab global contest for 14 – 18 to solid-like states year old students – TiO2 for filtering bacteria from the air in – Candidate vaccines for Salmonella and MRSA daycares – Candidate treatment for prostate cancer – Remotely-guided ultrasound for maternal – Candidate treatment for Duschenne’s muscular care in remote areas dystrophy 6 Science Mission directorate Uses of ISS • ISS Included as a plaorm in Science Mission directorated solicitaons since 2011 • Explorer-AO; SALMON: Stand Along Missions of Opportunity; SMEX: Small Mission Explorer; ROSES-APRA: Research Opportuni+es in Space and Earth Sciences – Astrophysics Research Announcement; Earth Venture • Selec+ons based on decadal survey priori+es among proposals on any plaorm • Astrophysics selected CREAM (Cosmic Ray Energe+cs and Mass) for ISS under ROSES-APRA • Astrophysics selected NICER (X-ray navigaon) for ISS under Earth Venture-Instrument • Funded by ESd with ISS support for integraon and poin+ng device • SAGE-III (upper atmosphere composi+on) • OCO-3 (atmospheric CO2 sources and sinks) • Instruments funded by ISS, support for science/ops from ESd • CATS (cloud lidar), technology demonstraon • RapidScat (winds, hurricanes), etc., fills data gap following QuikScat end of life • Internaonal Astrophysics instruments leveraging • CALET (Calorimetric Electron Telescope • JEM-EUSO (tentavely), JAXA/ESA/ASI/Roscosmos collaboraon 7 Expansion of ISS Research Capabili2es Enabling Greater Scien2fic and Commercial Return Rodent Research System Drosophila (Fruit Fly) Habitat and Centrifuge Microbial Observatory Advanced Plant Habitat Cold Atom Laboratory NanoRacks Enhancements CubeSat Launchers ACME Gaseous Combustion 8 What would it mean if ISS were extended beyond 2020 for research 9 60000 Increments 35-36 have averaged 40 hours/week For Increments 37-38 expect to average 42 hours/week! 50000 2020 40000 Transi+on to 4 USOS Crew Cumulave HRP 30000 Crew Hours Today Cum Crew Time Less HRP Hours 20000 3 Crew Base Cum Assembly >50% of Complete Crew me U+lizaon 10000 Transi+on to 6 Crew Occurs aer 2020 *HRP Crew Hours 0 available star+ng in Increment 29. Pre-decisional, For Internal Use Only 10 Cumula2ve # of Internal Experiment Opportuni2es Extension from 2020-2028 offers 85% more research 6000 Experiments are calculated as any inves+gaon going on during an Cumulave # of Experiments increment. Many experiments could take mul+ple increments to be 5000 completed but for comparison purposes all experiments here are normalized to require one increment to complete. 4000 3000 Transi+on to 4 crew + 2 more racks Final Rack Delivery 2000 Two Rack Deliveries 1000 0 Increment Number Fiscal Year 11 250 200 Title 150 Available Cum AMS Cum JEM EF Cum COL EPF Cum 100 ELC Cum Cumulave Site Years over Time 50 0 2013 2014 2015 2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 12 13 Enable a commercial demand driven market in LEO Over the next 10 years, the FAA predicts that commercial crew and cargo flight to the ISS will account for 57% of the non-GEO launch market - FAA 2013 Commercial Space TransportaGon Forecasts, May 2013 Worldwide there are 14-15 flights to the ISS per year - ISS represents a substan+al demand for LEO launch access - enables immediate access to space and ISS resources - enables new and innovave use of the complete ISS system 14 Enable a commercial demand driven market in LEO Extending ISS beyond 2020 enables a stable demand for commercial crew flights and a commercial demand for space research ISS to 2020 Commercial Crew 1 – 2 years of contracted flights CASIS <9 years of productive commercial utilization development ISS Operations and Utilization Commercial Crew ~10 years of crewed flights CASIS >17 years of commercial utilization 2015 2020 2025 2030 2035 2040 15 Enable a commercial demand driven market in LEO ISS can also enable the demand for commercial uses and applicaons in LEO that could lead to a commercially provided LEO plaorm - Utilize additional commercial crew seats and access to ISS for non-NASA uses including research, tourism or other private initiatives It is likely that NASA will s+ll have research needs in LEO beyond the life of the ISS ISS Operations and Utilization Commercial Crew ~10 years of crewed flights Commercial Research >17 years of scientific discovery since assembly complete 16 17 Global Explora2on Roadmap 18 Cri+cal path viewpoint for long duraon, deep space human spaceflight In-space segment - Life support - SpacecraK reliability, supportability and maintainability - Human performance for long duraGons in deep space - TransportaGon system performance Access to the surface: landing on, operang on, and then ascending from Mars 19 Staon is on the cri+cal path to geng humans to Mars In-space segment - Life support - SpacecraK reliability, supportability and maintainability - Human performance for long duraGons in deep space - TransportaGon system performance Access to the surface: landing on, operang on, and then ascending from Mars Cri+cal path research and demonstraon ac+vi+es onboard the ISS will not be complete un+l about the mid-2020’s +meframe 20 Closing the gap in Human Health and Performance The ISS is necessary to mi+gate 21 of the 32 human health risks an+cipated on exploraon missions Some of the primary drivers for the length of research onboard ISS are: - Number of subjects - Pharmacology - Visual Impairment and Intracranial Pressure - Muscle - Exploraon Medical Capability - Arrhythmia Given the current number of subjects expected, HRP research and mi+gaons for long duraon deep space missions should be mature enough by the mid-2020’s 21 Human Health and Performance Risk Reduc+on on ISS 22 Life support and habitaon systems ISS is the only plaorm to demonstrate the cri+cal systems and technology needed to get humans to Mars Some of the cri+cal demonstraons unique to deep space/long duraon missions are: - onboard analysis of crew health and atmospheric samples - ECLSS operaons without maintenance for 1 year or more - Crew exercise equipment operaon for 1 year without maintenance - demonstraon of exploraon EVA suit before deep space missions - docking system - Habitaon materials Based on current development and operaonal constraints, demonstraons will not be complete un+l the mid-2020’s 23 Exploraon Systems and Technology demonstraon 24 25 Basis for internaonal exploraon partnership The ISS Program is sufficiently complex to engage the major spacefaring naons in a common endeavor. If the ISS Partnership dissolves prematurely, it is not likely that a new partnership would be established any+me in the near future. ? 2015 2020 2025 2030 2035 2040 26 Countries that are following the U.S. leadership in space research, educaon, and exploraon 27 Staon is the glue that holds the internaonal human spaceflight community together With the ISS Program and Partnership fully engaged in human spaceflight beyond 2020, the Partnership can be maintained and enhanced to accomplishing our objec+ves. 2015 2020 2025 2030 2035 2040 28 How do we know when we are done with ISS Advance benefits to humanity Enable commercial demand driven through research LEO market Has the ISS life been fully exploited to Has a non-government commercial the benefit of science and research? crew/cargo transportation market DEMAND been established in LEO? Has a commercial LEO platform been Enable human missions beyond LEO established that could satisfy Has the critical technologies to conduct government needs? human and robotic exploration mission been demonstrated? Has a non-government commercial demand for micro-gravity research and Has the fly off plan to reduce human application been established? health and performance risk for long duration deep space mission been Basis for internaonal
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