SBIR-STTR Award

Modeling Rover Interactions with Lunar Regolith in Permanently Shadowed Regions
Award last edited on: 6/23/2022

Sponsored Program
SBIR
Awarding Agency
NASA : JSC
Total Award Amount
$884,814
Award Phase
2
Solicitation Topic Code
Z5.05
Principal Investigator
Ryan Garvey

Company Information

Blueshift LLC

575 Burbank Street Unit G
Broomfield, CO 80020
   (303) 953-0297
   N/A
   www.blueshiftusa.com
Location: Single
Congr. District: 02
County: Broomfield

Phase I

Contract Number: 80NSSC20C0614
Start Date: 7/31/2020    Completed: 3/1/2021
Phase I year
2020
Phase I Amount
$124,927
Blueshift, LLC doing business as Outward Technologies proposes to develop a Discrete Element Method (DEM) modeling framework using open-source software to simulate the combined thermal and mechanical interactions between rovers and regolith in Permanently Shadowed Regions (PSRs) at the lunar poles. This proposed set of numerical tools innovates on the current state of the art by explicitly solving for both thermal and mechanical interactions between rover components and regolith, and by the inclusion of volatiles such as water ice of multiple forms (e.g. vapor deposited “frost”, blocky deposits, and icy regolith mixtures) in a grain-based DEM model. Rover components including probes, drills, wheels, and soil sampling equipment will be simulated using coupled FEM software to reduce computation time. A coupled thermo-hydro-mechanical model will further be explored for its suitability in simulating volatile phase change and gas transport through cryogenic regolith as represented by a bonded-particle DEM. These numerical modeling capabilities will be integrated within a single, easy to use simulation framework for approximating thermal and mechanical interactions between rovers and regolith across ranges of possible conditions which may be encountered in and near PSRs on the Moon. These combined numerical tools will enable NASA and its partners to inexpensively evaluate hardware designs for lunar ISRU missions aimed at exploration and prospecting for volatiles. These improved modeling capabilities will further de-risk planned missions to the lunar south pole by identifying successful control strategies and hardware designs for ISRU sampling, material handling, increased rover operability, and surviving the lunar night, leading to more rugged and capable rovers for lunar polar missions while reducing their costs related to development and testing. Potential NASA Applications (Limit 1500 characters, approximately 150 words) This project leads to many potential NASA applications including the design and evaluation of rovers and sampling equipment for use in lunar polar regions for ISRU prospecting and exploration missions. The proposed DEM-FEM coupled software and its associated advancements will bring additional knowledge to the challenges faced in lunar polar missions while presenting a low-cost evaluation tool for hardware design, rover control strategies, and volatile sampling. These improvements will lead to lower cost lunar ISRU missions with reduced risk. Potential Non-NASA Applications (Limit 1500 characters, approximately 150 words) By increasing the sampling of the high-dimensional design space of DEM microscale input selection, Outward Technologies will be able to gain a competitive advantage in thermo-mechanical DEM models related to granular mechanics and will be able to incrementally increase our customer base, tailoring services to companies in the field of powder handling, pharmaceuticals, oil and gas, and mining.

Phase II

Contract Number: 80NSSC21C0483
Start Date: 8/3/2021    Completed: 8/2/2024
Phase II year
2021
Phase II Amount
$759,887
Blueshift, LLC doing business as Outward Technologies proposes to develop a coupled Discrete Element Method (DEM) and Finite Element Method (FEM) modeling framework using open-source software to simulate the combined thermal and mechanical interactions between rovers and regolith in and around Permanently Shadowed Regions (PSRs) on the Moon. This proposed set of numerical tools innovates on the current state of the art by simulating the thermomechanical response of lunar soil containing volatiles and by explicitly modeling volatile sublimation and advection through an ice-regolith mixture. A grain-based DEM model with user-defined soil compaction, grain shape, and particle size distributions will be coupled with FEM software to reduce computation time, enabling rover components including wheels, probes, and soil sampling equipment. This comprehensive modeling framework will be calibrated and validated through small-scale laboratory experiments for simulating bulk thermal conductivity, shear response, and penetration resistance of ice-regolith mixtures in cryogenic vacuum conditions. Sublimation will be evaluated in these experiments and models, as will deposition of water ice and formation of cemented icy-regolith. These combined numerical tools will enable NASA and its partners to inexpensively evaluate hardware designs for lunar ISRU missions aimed at exploration and prospecting for volatiles at the lunar poles. These improved modeling capabilities will further de-risk planned missions to the Moon by helping to identify successful control strategies and hardware designs for increased rover operability, ISRU sampling, material handling, and surviving the lunar night, thereby leading to more rugged and capable rovers for lunar polar missions while reducing their costs for development and testing. Potential NASA Applications (Limit 1500 characters, approximately 150 words): The Phase II leads to several potential NASA applications including the design and evaluation of rovers and sampling equipment for use in lunar polar regions for ISRU prospecting and exploration missions. The proposed DEM-FEM coupled software and its associated advancements will bring additional knowledge to the challenges faced in lunar polar missions while presenting a low-cost evaluation tool for hardware design, rover control strategies, and volatile sampling. These improvements will lead to lower cost lunar ISRU missions with reduced risk. Potential Non-NASA Applications (Limit 1500 characters, approximately 150 words): By increasing the sampling of the high-dimensional design space of DEM microscale input selection, Outward Technologies will be able to provide automated calibration services for companies and users of thermo-mechanical DEM models and provide improved numerical models to companies in the fields of powder handling, pharmaceuticals, oil and gas, and mining. Duration: 24