The system extracts water from lunar regolith and includes a regolith intake having a digging bucket that collects lunar regolith soil and a gravel separator that separates and discharges gravel and passes a mixture of ice-regolith powder having ice grains that are about 10-100 microns along the conveyor. A pneumatic separator receives the ice-regolith powder and pneumatically splits the ice-regolith powder into streams of different sized lithic fragments and ice particles per the ratio of inertial force and aerodynamic drag force of the lithic fragments and ice particles. Each split stream may include a magnetic separator that separates further the magnetic and paramagnetic lithic fragments from ice particles to discharge up to 80 percent of lithic fragments to slag.

A system and apparatuses for breaking down and collecting asteroids. The asteroid miner apparatus comprises a body, an aperture, a plurality of holes, a plurality of speakers, a drill, an attachment piece, a fan, a baggage, and a set of air compressors. The drill and plurality of speakers are attached to the body to break down matter. The set of air compressors expel air through the plurality of holes to create an atmosphere around the body. The fan is attached to the body to create a current of air though the aperture. The baggage is attached to the body to collect pieces of asteroid. The system comprises a plurality of asteroid miners and an attachment piece to connect the asteroid miners. The system may be placed around an asteroid or other piece of material to break down the material and collect portions of the material.

A system and apparatuses for breaking down and collecting asteroids. The asteroid miner apparatus comprises a body, an aperture, a plurality of holes, a plurality of speakers, a drill, an attachment piece, a fan, a baggage, and a set of air compressors. The drill and plurality of speakers are attached to the body to break down matter. The set of air compressors expel air through the plurality of holes to create an atmosphere around the body. The fan is attached to the body to create a current of air though the aperture. The baggage is attached to the body to collect pieces of asteroid. The system comprises a plurality of asteroid miners and an attachment piece to connect the asteroid miners. The system may be placed around an asteroid or other piece of material to break down the material and collect portions of the material.

A system and method of extracting frozen water from soil or a regolith and capturing the water is provided. More specifically, the present disclosure relates to a water collection system to extract and collect water from regolith. The system is configured to heat the regolith in situ to a temperature at which frozen water in the regolith will vaporize. The water vapor is then captured and collected. In one embodiment, the system includes a power system to provide energy to the regolith to heat the regolith, an enclosure to trap the water vapor released from the heated regolith, and a container operably interconnected to the enclosure to collect the water vapor. In one embodiment, the system can be positioned at a production facility on the Earth, the Moon, Mars, or an asteroid.

A system and method of extracting frozen water from soil or a regolith and capturing the water is provided. More specifically, the present disclosure relates to a water collection system to extract and collect water from regolith. The system is configured to heat the regolith in situ to a temperature at which frozen water in the regolith will vaporize. The water vapor is then captured and collected. In one embodiment, the system includes a power system to provide energy to the regolith to heat the regolith, an enclosure to trap the water vapor released from the heated regolith, and a container operably interconnected to the enclosure to collect the water vapor. In one embodiment, the system can be positioned at a production facility on the Earth, the Moon, Mars, or an asteroid.

An exploration method includes: a step of exploring a natural resource on a satellite, a minor planet, or a planet; a step of acquiring the natural resource detected by the exploration; and a step of storing the acquired natural resource.

Cosmic ray and muon-catalyzed micro-fusion electrical generation provides electrical power for mining operations, including any asteroid habitats and mining equipment. The micro-fusion generator systems deploy deuterium-containing fuel material as a localized cloud interacting with incoming ambient cosmic rays to generate energetic fusion products. Dust or other particulate matter in the fuel material, in the localized cloud, and in the space surrounding the asteroid being mined converts some cosmic rays into muons that also catalyze fusion. The fusion products drive turbines to facilitate the electrical generation.

A mobile mining platform for operation on a lunar surface can excavate and deposit regolith into a mill. The mill can agitate at least a portion of the excavated regolith to release volatile gases from the portion of the excavated regolith, without heat being applied to the portion of the excavated regolith. A refinery can perform molecular separation of the released volatile gases. In some embodiments, pressure in the mill can be increased through introduction of a diluent gas into the mill, to improve the efficiency of pumping the released volatile gases from the mill to the refinery. In some embodiments, volatile liquids stored on the platform and/or generated by the refinery can be used to cool the released volatile gases prior to molecular separation of the released volatile gases. In some embodiments, the mill can separate and collect regolith material of different sizes for different uses.

A mobile mining platform for operation on a lunar surface can excavate and deposit regolith into a mill. The mill can agitate at least a portion of the excavated regolith to release volatile gases from the portion of the excavated regolith, without heat being applied to the portion of the excavated regolith. A refinery can perform molecular separation of the released volatile gases. In some embodiments, pressure in the mill can be increased through introduction of a diluent gas into the mill, to improve the efficiency of pumping the released volatile gases from the mill to the refinery. In some embodiments, volatile liquids stored on the platform and/or generated by the refinery can be used to cool the released volatile gases prior to molecular separation of the released volatile gases. In some embodiments, the mill can separate and collect regolith material of different sizes for different uses.

Systems and apparatus are disclosed for mining the permafrost at the landing sites using radiant gas dynamic mining procedures. The systems can comprise a rover vehicle with an integrated large area dome for cryotrapping gases released from the surface and multi-wavelength radiant heating systems to provide adjustable heating as a function of depth. Various antenna arrays and configurations are disclosed, some of which can cooperate for a specific aiming or targeting effect.