1 / 37

To Infinity, And Beyond!

To Infinity, And Beyond!. Providing Energy for Space Systems. NASA/NTSA Symposium Preparing for the Journey to Space: Energy 7 April 2006. Steven E. Johnson ISS Flight Controller NASA Johnson Space Center. Photo taken January 26, 2003 by the crew of Space Shuttle Columbia. Overview.

newton
Download Presentation

To Infinity, And Beyond!

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. To Infinity, And Beyond! Providing Energy for Space Systems NASA/NTSA SymposiumPreparing for the Journey to Space: Energy7 April 2006 Steven E. JohnsonISS Flight ControllerNASA Johnson Space Center Photo taken January 26, 2003 by the crew of Space Shuttle Columbia

  2. Overview • Objectives • Energy • Energy Systems • Solar Power • Energy Storage • Nuclear Power • Review • Theoretical Applications • Backup Material

  3. Learning Objectives • After reviewing the presentation, participants will: • List the three types of spacecraft power system types. • State advantages and disadvantages of spacecraft power system types. • Determine the appropriate power system for theoretical applications.

  4. EnergyIts All About Conversion • The Law of Conservation of Energy: Energy can be neither created nor destroyed, it can only be transformed (converted) from one form to another • Energy conversion systems are everywhere • Chemical to Thermal • Home furnace using oil, gas, or wood • Chemical to Thermal to Mechanical • Automobile engine • Chemical to Electrical • Fuel cell • Electrical to Mechanical • Electric motor • Electrical to Radiant • Toaster, light bulb • Power plants are energy conversion systems • On Earth and in space

  5. Energy Systems 101Powering Spacecraft *Current manned space systems use Photovoltaic and Chemical power

  6. Solar PowerApplications • Near Sun missions • Venus • Mercury • Outbound • Mars • Asteroids • Earth orbital • International Space Station • Mir • Skylab • Communication satellites • Earth observation satellites • Weather satellites • Global Positioning System • Surface • Mars Pathfinder • Mars Exploration Rover

  7. Solar PowerApplications Skylab ISS Mir Mars Exploration Rover Hubble GPS Mir

  8. Solar PowerEvaluation • Solar Power Advantages • Unlimited energy supply • Mission duration not limited to on-board energy consumables • Modular • Solar panel systems can be built independently of specific space system • Established manufacturing base • Cost effective • Proven technology does not require significant research expenditures • No energy by-products or waste material → Best option for long-duration near-sun missions

  9. Solar PowerEvaluation • Solar Power Disadvantages • Requires a significant illumination source • Sunlight strength diminishes as the distance from the sun increases • Solar illumination insufficient for most applications beyond Mars • Most solar-powered space systems require additional energy storage (battery) systems • Most free-flight systems are dependant on a vehicle control system to point the space craft and/or solar arrays → Unfeasible option for deep space missions

  10. Cassini Probe Energy StorageApplications Apollo Command Service Module Apollo Lunar Rover Gemini Space Shuttle EMU

  11. Energy StorageEvaluation • Energy Storage Advantages • Allows independent space system operation • Not dependent on illumination source • Solar pointing system not required • Most space craft require control systems for attitude control regardless of power system → Best option for limited-duration manned missions

  12. Energy StorageEvaluation • Energy Storage Disadvantages • Limited mission duration • Fuel or battery life are limited-quantity consumables • Limits mission durations to ~2 weeks • Requires custom-built system for each application • Fuel Cell systems produce by products (water) which must be stored/dumped → Unfeasible option for long-duration missions

  13. Nuclear PowerApplications Viking Voyager Ulysses Galileo Cassini Since 1961, 40 RTGs have been used on 22 US space systems.

  14. Nuclear PowerEvaluation • Nuclear Power Advantages • Provides a very long-term energy source • Supports mission duration of tens of years • Allows independent space system operation • Not dependent on illumination source • Solar pointing system not required • Most space craft require control systems for attitude control regardless of power system • Currently the only viable option for non-solar missions longer than ~2 weeks and missions traveling beyond Mars → Best option for deep-space unmanned missions

  15. Nuclear PowerEvaluation • Nuclear Power Disadvantages • Low power capability • Highest power application: Cassini, < 1 kW • Not practical for manned space systems • Expensive • Requires custom-built system for each application → Unfeasible option for manned missions

  16. Review • What are the 3 types of space power systems? • Solar power • Energy storage • Nuclear power

  17. Review • What is the primary advantage of solar power? • Unlimited energy supply • What is the primary disadvantage of solar power? • Requires a significant illumination source • What is the primary advantage of energy storage? • Allows independent operation • What is the primary disadvantage of energy storage? • Limited mission duration • What is the primary advantage of nuclear power? • Provides a very long-term energy source • What is the primary disadvantage of nuclear power? • Low power capability

  18. Theoretical Application 1 • Engineering is developing an Extra-Vehicular Activity (EVA) free-ranging, semi-autonomous robotic assistance device for ISS. • The robotic device will need to operate for the duration of an EVA (~7 hours) or be operated independently from ISS for external inspection and have a mass of 8 kg or less. • The robotic device will require the following systems • Video camera – 12 V, 100 W • Still-picture camera – 12V, 25 W • Flood light – 14 V, 250 W • Attitude control system – 8 V, 25 W • EMU-to-ISS Radio Signal Relay – 12 V, 80 W • Command & Telemetry System – 12 V, 60 W • What type of energy system should this system utilize?

  19. Theoretical Application 1 Energy Storage (battery)

  20. Theoretical Application 2 • A mission has been requested for sun surface observation and space environment sensing • A space system is required which will have the following mission parameters • Operate in a solar orbit between Venus and Earth for 4+ years • Observe the sun with filtered video and photographic equipment • Sense space weather events • Monitor solar electromagnetic, ultraviolet, infrared, and x-ray radiation • Send scientific data back to an Earth control center • What type of energy system should this system utilize?

  21. Theoretical Application 2 Solar Power

  22. Theoretical Application 3 • A space system is required to investigate Neptune • The mission will have the following requirements • Be inserted by a Delta II launch platform • Payload up-mass: 1,900 to 4,700 lb • Payload Diameter: up to 10 feet • Payload Length: up to 22 feet • Translate from Earth to Neptune in 14 years or less • Operate in orbit around Neptune for 2-4 years • Enter Neptune’s atmosphere on a ballistic trajectory and gather atmospheric data and imagery • Send scientific data back to an Earth control center • Receive instructions from an Earth control center • What type of energy system should this system utilize?

  23. Theoretical Application 3 Nuclear Power

  24. Summary • Space systems use three types of power systems • Each system has advantages and disadvantages • Space system and mission requirements dictate the appropriate energy system

  25. Back Up Material

  26. Contents • Low Earth Orbit Overview • ISS • Overview • Electrical Power System • Shuttle • Overview • Electrical Power System • EMU • Overview • Electrical Power System • References

  27. Low Earth Orbit (LEO)Overview Insolation (Sunlight) Earth Orbit Manned vehicle LEO altitude = 115-400 miles Orbital Period = ~90 minutes Insolation = ~45 minutes Eclipse = ~45 minutes Eclipse (Night) Diagram Not to Scale

  28. Manned Space Systems • There are currently manned space systems • ISS • Shuttle • EMU • ISS is powered by a solar power energy system • Also has an energy storage (battery) component • Shuttle is powered by a energy storage system • Fuel cell • EMU is powered by a energy storage system • Battery

  29. International Space StationOverview • International Space Station (ISS) is a manned Low-Earth Orbit vehicle • Launched in November 1998 • Manned since October 2000 • Mission Control Center (MCC) in Houston, TX maintains primary responsibility for vehicle monitoring and operation • There’s no cockpit in ISS – its ‘flown’ from MCC • Assembled up in stages, estimated completion of 2010 • ISS is the largest space vehicle ever flown • Currently • 170 feet long and 240 feet wide • Mass of > 404,000 lbs • Assembly complete • 240 feet long and 350 feet wide • Mass of > 1,000,000 lbs • Largest solar arrays ever flown • All electrical power is generated from solar energy • Each solar array is 120 feet long • Each of the 8 [assembly complete] solar arrays generates up to 16 kW of power

  30. International Space StationElectrical Power System • Energy is collected from solar radiation • Power is converted from collection (primary) power levels to user (secondary) power levels • Primary power is also stored in chemical batteries to be used in eclipse • Secondary power is distributed throughout the vehicle for system and user loads

  31. PVA SARJ From 2nd Power Channel PVR Blanket Blanket MBSU IEA Batt Batt Batt Batt Batt Batt PFCA PMCU PMCU DDCU Mast BCDU BCDU BCDU Various DDCUs, SPDAs & RPDAs Mast canister SPDA SSU DCSU C&C MDM C&C MDM Users RPDA ECU BGA DDCU PVCU PVCU Users Legend: Thermal cooling flow Control and data flow Energy Energy Power Power Power management and Photovoltaic Thermal collection storage conversion distribution control Control System (PVTCS) International Space StationElectrical Power System Batt (Battery) ECU (Electronics Control Unit) PVA (Photo Voltaic Array) BCDU (Battery Charge Discharge Unit) MBSU (Main Bus Switching Unit) PVCU (Photo Voltaic Control Unit) BGA (Beta Gimbal Assembly) RPDA (Remote Power Distribution Assembly) PVR (Photo Voltaic Radiator) C&C MDM (Command & Control Multiplexer-DeMultiplexer) PFCA (Pump Flow Control Assembly) SARJ (Solar Alpha Rotary Joint) DDCU (DC to DC Conversion Unit) PMCU (Power Management Control Unit) SPDA (Secondary Power Distribution Assembly) SSU (Sequential Shunt Unit)

  32. Space Transportation SystemOverview • The Space Transportation System is an ascent, Low Earth Orbit, and return space vehicle • Comprised of 3 elements • 2 Solid Rocket Boosters (SRBs) – Jettisoned ~2 minutes after launch and recovered by ship from Atlantic Ocean • External Tank – Provides 500,000 gallons of hydrogen and oxygen fuel to Shuttle Main Engines, jettisoned after fuel expended and burns up in Earth’s atmosphere • Space Shuttle orbiter – Orbits Earth for up to 18 days and then returns as a glider • First and only operational space vehicle which is reusable • SRBs, Shuttle orbiter, and main engines are refurbished and resupplied for subsequent missions • Only space system which allows heavy down-mass capability • Orbiter power is provided by 3 oxygen-hydrogen fuel cells • Each fuel cell generates up to 7 kW of continuous power • Each fuel cell can generate up to 16 kW of short-term (15 min) power • STS is the only manned US heavy-lift and ascent/return system • Weighs 4,500,000 lbs at lift off • Carries payloads up to 63,500 lbs • Crewed by up to 8 astronauts

  33. Extra-vehicular Mobility UnitOverview • The Extra-vehicular Mobility Unit (EMU) is a self-contained ‘spacesuit’ used by crewmembers to perform Extra-Vehicular Activity (EVA) • The EMU contains all necessary elements for a crewmember to operate outside of a vehicle • Battery power system • Pressurized environment • Life Support System • Communication system • Computer, data, and biomedical monitoring system • Urine collection device • Lighting and camera system • Drinking water • EMU can operate independently for ~7 hours • The air scrubbing cartridge lifetime is the limiting factor in EVA • Similar Russian designed and built EMU (“Orlan”) used on ISS

  34. Extra-Vehicular Mobility Unit Power System • EMU battery operates at 16.8 V • Capacity = 26.8 A-Hr • Produces ~70 W of power • Useful power supplied for ~7 hours • Separate individual batteries are used for other EMU systems • Helmet light • Helmet camera • Glove heaters • Simplified Aid For EVA Rescue (SAFER)(contingency jet pack)

  35. Extra-Vehicular Mobility Unit Power System

  36. Extra-Vehicular Mobility Unit Power System ISS Aux Power SSER Batt/SCU Sw Coolant Iso Vlv Motor EMUBatt Fan Sw Fan Pump H2O Sep Feedwater Iso Vlv H2O Sw CWS RTDS CCA Display Sw OBS DCM Batt (Battery) SSER (Space-to-Space EMU Radio) Iso Vlv (Isolation Valve) SCU (Signal Conditioner Unit) H2O Sep (Water Separator) Sw (Switch)CWS (Caution & Warning System) RTDS (Real Time Data System) CCA (Communication Carrier Assembly)DCM (Display & Control Module) OBS (Operational Bioinstrumentation System)

  37. References • NASA Homepage www.nasa.gov • NASA Missions website http://www.nasa.gov/missions/highlights • NASA Human Spaceflight website http://spaceflight.nasa.gov • Wikipedia http://www.wikipedia.com • The magnificent brain of Steven Johnson steven.e.johnson@nasa.gov 281-483-9534

More Related