Difference between revisions of "Space Resource Generation"
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==Roadmap Overview== | ==Roadmap Overview== | ||
Space Resource Generation refers to the thermal or chemical conversion processes to generate resources in space environments which relax launch requirements, and subsequently enable a range of exploration and commercial activities in space. The | Space Resource Generation refers to the thermal or chemical conversion processes to generate resources in space environments which relax launch requirements, and subsequently enable a range of exploration and commercial activities in space. | ||
NASA's Artemis program plans to head back to the Moon this decade in a phased approach to build up lunar activity, including a commercial presence, to serve as a proving ground for human missions to Mars. The space industry is set to be valued at ~1.8 trillion USD by 2035, with increasing access to space enabled through the reduction of launch costs. The need for space resource generation technologies is driven by increasingly longer stays off-world at destinations of increasing distance from Earth, where technologies that recycle utilize available resources can make these missions safer, more Earth-independent, and even enable cost-savings. | |||
Space resource technologies can be used for life-support among numerous human space stations, propellant generation, metal extraction and production, radiation shielding, landing pad production, etc. Space resource generation includes both “in-situ resource utilization” (ISRU) and resource recycling technologies, because these two categories of technologies share similar operating principles and should be compared using the same Figures of Merit (FOMs) to elucidate the different value in different mission profiles. | |||
Revision as of 13:01, 10 October 2024
Roadmap Creators: | Lanie McKinney
Technology Roadmap Sections and Deliverables
This technology roadmap has the unique identifier:
1SRG - Space Resource Generation
The number 1 denotes that this is a Level 1 technology roadmap at the market level. In reference to our technology, Level 1 encompasses all conversion technologies used in space, Level 2 describes the product level, for example oxygen generation. Level 3, the system level, could reference a solid oxide electrolysis system for oxygen production and Level 4, the subsystem level could represent the material used for the electrode stack.
Roadmap Overview
Space Resource Generation refers to the thermal or chemical conversion processes to generate resources in space environments which relax launch requirements, and subsequently enable a range of exploration and commercial activities in space. NASA's Artemis program plans to head back to the Moon this decade in a phased approach to build up lunar activity, including a commercial presence, to serve as a proving ground for human missions to Mars. The space industry is set to be valued at ~1.8 trillion USD by 2035, with increasing access to space enabled through the reduction of launch costs. The need for space resource generation technologies is driven by increasingly longer stays off-world at destinations of increasing distance from Earth, where technologies that recycle utilize available resources can make these missions safer, more Earth-independent, and even enable cost-savings.
Space resource technologies can be used for life-support among numerous human space stations, propellant generation, metal extraction and production, radiation shielding, landing pad production, etc. Space resource generation includes both “in-situ resource utilization” (ISRU) and resource recycling technologies, because these two categories of technologies share similar operating principles and should be compared using the same Figures of Merit (FOMs) to elucidate the different value in different mission profiles.
Design Structure Matrix (DSM) Allocation
The 1-SRG tree from the DSM above shows us that the Space Resource Generation (1-SRG) has a range of
part of a larger company-wide initiative on electrification of flight (1ELE), and that it requires the following key enabling technologies at the subsystem level: 3CFP Carbon Fiber Polymers, 3HEP Hybrid Electric Propulsion and 3EPS Non-Propulsive Energy Management (e.g. this includes the management of the charge-discharge cycle of the batteries during the day-night cycle). In turn these require enabling technologies at level 4, the technology component level: 4CMP components made from CFRP (spars, wing box, fairings …), 4EMT electric machines (motors and generators), 4ENS energy sources (such as thin film photovoltaics bonded to flight surfaces) and 4STO (energy storage in the form of lithium-type batteries).
Roadmap Model using OPM
We provide an Object-Process-Diagram (OPD) of the 1SRG roadmap in the figure below. This diagram captures the main product of the roadmap (Space Resource Generation Systems), and decomposes the various possible common subsystems of these technologies (acquisition, heating, compression, conversion, separation stages …), its characterization by Figures of Merit (FOMs) as well as the main processes (Acquiring, Converting).
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An Object-Process-Language (OPL) description of the roadmap scope is auto-generated and given below. It reflects the same content as the previous figure, but in a formal natural language.
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Figures of Merit
The table below show a list of FOMs that can be used to assess Space Resource Generation Technologies.
| Figure of Merit | Unit | Description |
|---|---|---|
| Production Rate | kg/hr | the rate of generating a target product |
| Lifetime Embodied Energy | MJ/kg | the thermodynamic sum of past, present and future work required to create, operate, maintain and decommission a system per kg of product produced |
| Specific Energy Consumption | kWh/kg | total energy required to produce a kg of product |
| Launch-adjusted Atom Economy | % | ratio of mass of useful product generated to the total mass of reactants and launched mass needed |
Besides defining what the FOMs are, this section of the roadmap should also contain the FOM trends over time dFOM/dt as well as some of the key governing equations that underpin the technology. These governing equations can be derived from physics (or chemistry, biology ..) or they can be empirically derived from a multivariate regression model. The table below shows an example of a key governing equation governing (solar-) electric aircraft.
