solar sail design and qualification - the planetary · pdf filelightsail-1™ solar sail...
TRANSCRIPT
LightSail-1™ Solar Sail Design and Qualification
Chris Biddy,
Stellar Exploration Inc.
41st Aerospace Mechanism Symposium
LightSail-1™ Introduction
• Project of The Planetary Society
• Completely privately funded through member donations
Objectives are to:
• Demonstrate viability of Solar Sails – Ability to alter orbit energy in positive direction
– Ability to manage orbital energy
– Ability to control spacecraft under solar sail power
• Develop and demonstrate key technologies – Sail deployment
– Sail material management during flight
– Gossamer structure dynamics
• Demonstrate pathway to deep space with solar sails
Requirements are to:
• Achieve greater sail area/mass than COSMOS-1
ACS Orbit Raising Mode
• Orbit raising will be accomplished by 90 degree pitch
maneuver
• >800 km orbit needed for SRP > Aerodynamic Drag
LightSail-1™ Design Challenges
• How to package the sail and booms in the
allowable volume
• How to manage boom strain energy while
stowed and during deployment
• How to control the sail deployment
• How to constrain sail material and booms prior
to deployment (including during launch)
• How to manage sail material during deployment
LightSail-1™ Configuration
• 3U CubeSat Spacecraft organized into 3
sections
• Avionics Section/Sail Storage (~2U)
– Contains Avionics Board, radio, Sensor
Interface board, Battery Pack, 3- single
axis MEMS Gyros, 3 Torque Rods, 1
Momentum Bias Wheel, a 3 axis
accelerometer, and sail storage cavity
• Deployer Section (~0.5U)
– Houses 4 x 4 meter TRAC booms
• Payload Section (~0.5U)
– Houses boom drive motor and gear train,
storage area for cameras (attached to
deployable arrays), monopole antenna,
deployable array burn wire mechanism
and a 3-axis accelerometer
Boom
• Lightsail-1™ uses the AFRL developed TRAC (Triangular Rollable
and Collapsible) boom
• The TRAC boom can be collapsed and rolled around a spindle
providing a compact storage solution
• Booms “self-deploy” due to stored strain energy however an external
torque is required to deploy the sail
– Booms are driven by a brushless dc motor coupled with worm drive
gear train
Deployed TRAC boom
Boom Deployer
• Key Requirements Store and deploy 4m booms
– Control deployment rate so as to not damage booms or sail blades
• Deployer Functions – Provide normal reaction force against booms at all times (required to keep booms “pinched”)
– Provide for smooth deployment (no interference between booms and deployer components)
– Guide booms at deployer exit
• Deployer Features – Bearing supported spindle
– Rocker arm tensioner with flexure springs
keep booms against spindle
– Delrin AF boom guides at deployer exit
• Deployer Size – Maximum height = 5.5 cm
– Maximum width = 10 cm
Deployer
• Rocker arms deflect flexure springs during boom winding
• Flexures stick out past solar panel plane only at the end of boom
deployment (after solar cell panels are deployed)
• Booms exit at corners (denoted by arrows)
Fully deployed state (flexure springs not deflected) Fully stowed state (flexure springs deflected)
Deployer Lessons Learned
• Significant boom axial force required to deploy sails
• Boom management within deployer critical for reliable
deployment of the sail
– Determined that the flexure spring rate affected required motor
torque to deploy the sail
– Determined that high coefficient of friction is
required between adjacent boom wraps
• Difficult to predict cold performance
– Deployment motor required additional
current as temperature decreased
Flight Deployer and payload section
Sail Folding and Storage
Z-fold sail quadrant from outside edge to
center
Z-fold sail from
center outward
to form
“wedge”
shaped fold
Folded sail
quadrants fit
into wedge
shaped
cavities and
restrained by
deployable
Solar Cell
panels
• Sail quadrants are z-folded in two directions to form a wedge shaped folded
cross-section
• Z-fold provides a path for gases to escape
• Verified with vacuum chamber test
Sail Attachment
• The triangle shaped sail quadrants are attached to the spacecraft at
all three corners
– At the base of the sail storage cavity and the tips of the booms
• Metal grommets and split rings were used to connect the sails to the
booms with extension springs in series to account for thermal
distortions
Sail quadrant to boom attachment Sail base grommet
Sail Management
• The stowed sail is held in place with the deployable arrays
• During deployment the sail is withdrawn from the storage cavities 1
fold at a time due to a slight interference fit between the folded sail
quadrants and the storage cavity
TRAC Boom
Tensioned Sail
Remaining Sail Material
Engineering model deployment testing Stowed Flight unit
Qualification Testing
• Qualification testing included sail deployments before and after
TVAC and random vibe tests
• Off-loading was achieved by building a table to support the booms
during testing
Sail deployment table
LightSail-1 undergoing random
vibration testing at Cal Poly
Onboard camera view of sail deployment
Conclusion
• LightSail-1™ is ready for launch
• Reliable sail deployment has been demonstrated (over a dozen
successful deployments)
• LightSail-1™ achieved ~150g/m^2 with an 80:1 pre to post
deployment ratio
Questions?