electrical power systems (eps) for lunar exploration science working group (leswg)
DESCRIPTION
Electrical Power Systems (EPS) for Lunar Exploration Science Working Group (LESWG). Bob G. Beaman 11 January 2007. Power Branch Objectives. Provide Knowledge and background of the Code 563 Power Branch experience and capabilities. - PowerPoint PPT PresentationTRANSCRIPT
BGB 1
LOGO.049
Goddard Space Flight Center
Electrical Power Systems (EPS) for Lunar Exploration Science Working
Group (LESWG)
Bob G. Beaman11 January 2007
BGB 2
LOGO.049
Goddard Space Flight Center Power Branch Objectives
• Provide Knowledge and background of the Code 563 Power Branch experience and capabilities.
• Listen and work with Scientist on future Lunar Science proposals.
• Provide assistance on Proposal submissions• Feed back into Technology Development needs to
support Lunar Science.• Ability to build, test, launch and operate space
components and systems.• Point of Contact
– Bob G. Beaman 6-2538– Thomas Y. Yi 6-5845
BGB 3
LOGO.049
Goddard Space Flight Center
Power Branch Design Capabilities
• Sizing and Study of Mission Craft parameters to meet Science Objectives.
• Defining derived EPS requirements for Mission Craft and Science Instruments
• Mission Craft may be a orbiting spacecraft like Lunar Reconnaissance Orbiter (LRO) or perhaps several forms of surface crafts.
• Ability to work with Integrated Design Capability (IDC) ISAL and IMDC study planning and design sessions.
BGB 4
LOGO.049
Goddard Space Flight Center Lunar Environment
• Orbital Environment• Surface Environment
– Temperature range +120 deg C to -160 deg C– 14 day, (24 hour days) in sun and night– Almost no atmosphere, direct effects from solar mass
emissions– Loose soil and dust on surface.– 1/6 of Earths Gravity
BGB 5
LOGO.049
Goddard Space Flight Center
GSFC Power Systems Branch Capabilities
• World class development laboratories and experience
• Leading technology development to improve overall power system performance and flexibility
– Continuously striving to reduce cost, mass, and power consumption of electrical power systems
• High power output capabilities/condensed packaging, working closely with industry to develop radiation hard high reliability critical components
• Adopting new FPGA capabilities to reduce power system electronics size and complexity resulting in fewer EEE parts in design
• More software driven high reliability systems approach
• Optimizing overall power system parameters to reduce cost and provide more efficient delivery systems
BGB 6
LOGO.049
Goddard Space Flight Center
Power System Development Flexibility/Expertise
• Nanosat Integrated Power Systems– Nanosat technology (ST-5) for low power
levels utilizes low voltage approach (6-8 Vdc unregulated bus) to provide low power solution while integrated with observatory avionics in one component
• Small Explorer Class Power Systems– Unique development of “Feed Forward”
performance control loop for Small Explorers class missions (Triana) to reduce size and increase efficiency for system sizes up to 500 Watts
• Medium Class Power Systems– Condensed single fault tolerant design for
moderate/high power 28V systems (SDO) provides high reliability and modular functionality for systems up to 1500 Watts
• High Voltage/High Power Systems– First NASA high voltage 120 VDC
observatory launched in December, 1999 (EOS Terra) provided high reliability and low harness mass/low harness loss solution for systems typically larger than 1500 Watts
BGB 7
LOGO.049
Goddard Space Flight Center
Power Generation/Collection
• Solar Arrays. Capability to work with many different types of Solar Array: Silicon 11.2 % ~25 W/kg to Triple junction Gallium Arsenide 28.5 % ~150 W/kg.
• Solar Array Development areas.– Electrostatically Clean Arrays– FAST Cost Approximately 8 times a “vanilla” array– SBIR with Composite Optics Inc., now ATK, for an Inexpensive,
Reliable ECSA.– THEMIS Cos Approximately 1.3 times a “vanilla” array– SBIR on-going with AEC-Able, now ATK, for an ECSA
• Other Power Sources– Radioisotope Thermoelectric Generators (RTG)– Solar/Lunar Thermionics
BGB 8
LOGO.049
Goddard Space Flight Center
Power System Electronics
• Modular Design• Avionics Concepts• Science interface
compatibility• Performance parameters
– XTE 1995• 40.4 Watts/kg• 0.03 Watts/cm3
– MAP/EO-1 2001• 70.7 Watts/kg• 0.04 Watts/cm3
– SDO 2008• 65.6 Watts/kg• 0.05 Watts/cm3
– LRO 2008• 123.7 Watts/kg• 0.13 Watts/cm3
Solar Array Module
x14
Solar Array Segments
28v
Bu
s B
ack
pla
ne
Ibatt
Batt tlmRly Drv
Special Commands I/F
SA temp
Uart / Rs422
1553
Test Con.5v & +/-15v
PSE Monitor Card
Test Con.
DPC/GSE input
x12 switched
x3 unswitched
Output Module Loads
Sec
ond
ary
Bu
s
x12 switched
x3 unswitched
Output Module Loads
x12 switched
x3 unswitched
Output Module Loads
x12 switched
x3 unswitched
Output Module Loads
2
1
11w/ OVbckp
BGB 9
LOGO.049
Goddard Space Flight Center Energy Storage
• Batteries GSFC “Pioneered” the rechargeable secondary battery for aerospace application since early 1960
• Identify the maturity of a rechargeable secondary battery cell chemistry for aerospace use
• Test and validate the matured cell for aerospace application
• Design, test, qualify, and infuse the advanced battery into spacecraft
• Manage on board battery operation for a successful mission
• Structural Battery• Micro Battery• Flywheels• Fuel Cells
50 Ah XTE/TRMM SNiCd 80 Ah HST NiH2 ORU
NiH2
Li-Ion
NiH2 vs. Li-Ion 7.5 Ah ST-5 Li-Ion
Structural Battery Micro Battery Flywheel
BGB 10
LOGO.049
Goddard Space Flight Center
Instrument Converter Technologies
• Custom Designs for Unique Instrument Power Requirements– Low Voltage– High Voltage– Low Noise– Isolated Outputs– Radiation Hardened/Tolerant Components
BGB 11
LOGO.049
Goddard Space Flight Center
Power Branch Summary
• The Power Branch is willing to listen and add our expertise to the Lunar Science future proposals.