A Design Concept for a Robotic Lunar Regolith Harvesting System
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A Design Concept for a Robotic Lunar Regolith Harvesting System Stanford Lunar Regolith Excavation Presentation Authors: Matthew Maniscalco, Nicolas Lee, Nathan Salowitz, Forrest Hetherington, Elizabeth Grote, Shandor Dektor, and Professor Robert Twiggs ICRA '07 Space Robotics Workshop April 14, 2007, Rome, Italy
description
ICRA '07 Space Robotics Workshop April 14, 2007, Rome, Italy. A Design Concept for a Robotic Lunar Regolith Harvesting System. Stanford Lunar Regolith Excavation Presentation Authors: Matthew Maniscalco, Nicolas Lee, Nathan Salowitz, Forrest Hetherington, - PowerPoint PPT Presentation
Transcript of A Design Concept for a Robotic Lunar Regolith Harvesting System
A Design Conceptfor a Robotic Lunar Regolith Harvesting
System
Stanford Lunar Regolith Excavation Presentation Authors:Matthew Maniscalco, Nicolas Lee, Nathan Salowitz, Forrest Hetherington, Elizabeth Grote, Shandor Dektor, and Professor Robert Twiggs
ICRA '07 Space Robotics Workshop April 14, 2007, Rome, Italy
Presentation Outline
• Motivation for Robotic Regolith Harvesting• Lunar Environment• Robotic System Requirements
– Tasks– Constraints
• System Concept– Modularity– Semi-Autonomous Control System– Supporting Infrastructure
http://universe-review.ca/I14-13-Moonbase.jpg
Motivation for Robotic Regolith Harvesting
• Establish a permanent moon base– Robotic preparation of station and site– In-situ resource utilization (ISRU)“Never send a human to do a robot’s job”
• Save money • Reduce risk
http://universe-review.ca/I14-13-Moonbase.jpg
Lunar Environment• Radiation
– Lunar radiation environment consists of solar wind, solar flares, and cosmic rays
– Destructive for both humans and machinery
• Composition of regolith– Oxides of:
Si, Fe, Al, Ca, Mg, Ti, Na, Cr, Mn, K, P, and S
• Uses/products from regolith– Oxygen– Building materials – Helium-3– Ultimately more complex
products• Solar panels, computer chips,
fiberglass www.moonminer.com/MOONDUST-ON-BLACK-RSC.JPG
Lunar Environment• Adverse regolith characteristics –
dust– Fine– Sharp– Electrostatically attracted
http://www.gc.maricopa.edu/earthsci/imagearchive/Coralpnk1.JPGhttp://www.astro.virginia.edu/class/oconnell/astr121/moondust.html
Robotic System Constraints Dust Migration
• Anthropogenic– Launches and landings– Construction– Regolith excavation
• Natural– Terminator – Day night ion charging– Meteor impacts
http://vesuvius.jsc.nasa.gov/er/seh/sei52.GIF
Robotic System Requirements
• Tasks– Construction– Harvesting of Regolith
• Constraints– Radiation Protection– Dust Mitigation– Operational Efficiency
http://ares.jsc.nasa.gov/HumanExplore/Exploration/EXLibrary/DOCS/Images/EIC033-2.GIF
Robotic System TasksConstruction
• Assembly tasks• Radiation protection
– Bury manned structures– Robotics reduce EVA trips/time
• Dust mitigation– Reduced EVA’s– Constant Cleaning
• Landing and launch port• Solar collection stations• Rover repair station• Cleaning systems (electrostatic, ultrasonic, physical
sweepers, fluids)
http://www.affordablespaceflight.com/moonbase.gif
Robotic System Tasks
Harvesting Regolith
• Harvesting tasks– Clean– Clear– Dig– Transport
http://www.psrd.hawaii.edu/WebImg/lunox.gif
Robotic System Constraints Radiation Protection
• Radiation hardened electronics• Robust and simple software
– Suitable for rad hard (slower) processors – Failures easily detected and corrected
Robotic System Constraints Dust Mitigation
• Four level approach– Prevention– Containment– Equipment Protection– Durable Design
http://nssdc.gsfc.nasa.gov/planetary/lunar/images/as11_40_5878.jpg
Robotic System Constraints Operational Efficiency
• Problems– Specific cost of launch– Different rates of wear on equipment – Downtime for repair and recharge
• Solution– Modularity
• Less total equipment• Replace worn parts• Operate during repair & recharge
http://www.nasa.gov/images/content/149768main_calv_launch_330.jpg
The System Concept• Modularity
– The Core Platform– The Suite of Modules
• Semi-Autonomous Control System • Supporting Infrastructure
The System ConceptModularity
• Flexibility of 3-point PTO for tractors– Maximizes functions performed by mass
• Worn out parts can easily be replaced– Minimizes downtime for part repair– Allows full use of parts with different lifespans
• Swappable batteries– No recharge downtime for rovers
The System ConceptThe Core Platform
• Power system, electronics, control, data handling, and communication
The System ConceptThe Core Platform
• Interface: 3-points and wiring
The System ConceptThe Suite of Modules
• Blade Actuator Module (BAM) - Bulldozer• Regolith Transportation Module (RTM) - Truck• Integrated Conveyor Module (ICM) - Excavator
– Rotating Wheel Attachment (RWA) - Wheel digger– Rotating Sweeper Attachment (RSA) - Power broom
• Articulated Digging Module (ADM) - Backhoe• Articulated Loading Module (ALM) - Loader
The System ConceptThe Suite of Modules
• Blade Actuator Module (BAM) - Bulldozer
The System ConceptThe Suite of Modules
• Regolith Transportation Module (RTM) - Truck
The System ConceptThe Suite of Modules
• Integrated Conveyor Module (ICM) - Excavator
The System ConceptThe Suite of Modules
• Integrated Conveyor Module (ICM) - Excavator– Rotating Wheel Attachment (RWA) - Wheel digger– Rotating Sweeper Attachment (RSA) - Power broom
The System ConceptThe Suite of Modules
• Articulated Digging Module (ADM) - Backhoe
The System ConceptThe Suite of Modules
• Articulated Loading Module (ALM) - Loader
The System ConceptControl System
• Machine tool style task assignments– High level thinking and analysis
done elsewhere, CNC script sent robots.
• Semi-autonomy– Advantages over haptic, force-
feedback– Advantages over fully autonomous
http://www.belmont.k12.ca.us/ralston/programs/itech/SpaceSettlement/spaceresvol4/images/humanfig19.JPG
CommandScript
ScriptedTask
Completed
SensorData
Acquired
Obstruction
OperatorAnalysis
NoInterference
BeginExcavation
Process
The System ConceptControl System
The System ConceptSupporting Infrastructure
• Solar Recharging Station• Repair/Reassignment Shop• Regolith Processing Facility
– Conveyor system• Human Habitat• The Port – landing and launch
http://www.hardyart.demon.co.uk/webimage/advbase.jpg
The System ConceptSupporting Infrastructure
Lower DustTolerance
Higher DustTolerance
Geographic Separation
ThePort
Habitat
SolarStation
RepairShop
RegolithProcessing
Facility
RegolithExcavation
andConveyor
Area
Conclusion• Modular, Semi-Autonomous System
– Lowers cost– Increases power and mass efficiency– Increases versatility– Reduces human exposure to dust and
radiation– Harvests resources and frees astronauts for
less mundane tasks
http://www.thespacereview.com/archive/93a.jpg
CreditsThanks to:
SSDL, Stellar Solutions, Pumpkin Inc., Stanford on the Moon, andNASA for public domain imagesAdditional Student Contributors:James Mack, Dave Johnson, Katie Davis, Geoffrey Bower, Jordan McRae
http://icb.nasa.gov/2003_Annual_Report/lunar_rover_II.jpg
The End
![LUNAR REGOLITH PROPERTIES CONSTRAINED BY LRO DIVINER … · Radiometer Experiment onboard LRO [1] is an instru-ment measuring the surface bolometric temperature of the regolith. It](https://static.fdocuments.net/doc/165x107/5f35d95c40a16530e07709a6/lunar-regolith-properties-constrained-by-lro-diviner-radiometer-experiment-onboard.jpg)
