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#1 Re: Exploration to Settlement Creation » Ring Habitat on Mars Doughnut Torus » Yesterday 20:10:44
To build for 1,000 a dome with isogrid structure of mars materials to use and do develop of stainless insitu materials is going to be a 40 year plus plan involving heavy mining and smelting, with a 1-meter deep, 8x8 km pit of regolith necessary for material to sustain a large population's infrastructure.
Leaving even more time for getting the cast basalt processing for insertion into the grid.
#2 Re: Exploration to Settlement Creation » WIKI Project Designing for Mars » Yesterday 19:55:58
more dummy pages
#3 Re: Exploration to Settlement Creation » WIKI Project Designing for Mars » Yesterday 19:55:53
make a building that can house 1,000 crew is just a multiplier for what needs to be setup for all space requires from power, life support, greenhouse, medical care, ect these are not established for mars or for the moon in there entirety.
Picking any number to support any person is going to fail for any construction when quotative numbers are not proven.
That's like saying you only need 8 gallons of water to drink for the whole mission with none on the other end once you are there.
Ignoring facts of who, what, where, when and more 20 questions are blank.
#4 Re: Exploration to Settlement Creation » KBD512 Biosphere structure of cast basalt » Yesterday 19:54:29
Isogrid technology, which involves creating rigid, lightweight triangular-stiffened structures, is a critical technique for designing space-hardened habitats and shells on Mars. While specific "plug-and-play" software labeled "Isogrid Maker for Mars" does not exist, aerospace and structural engineers use several advanced CAD and simulation tools to model these, often utilizing additive manufacturing (3D printing) for implementation.
Key Software and Modeling Techniques for Mars Domes:
Autodesk Fusion 360: Used for parametric modeling of isogrid structures. It allows engineers to create, test, and adapt the geometry of triangular ribs, which is critical for optimization.
Continuous Composites (CF3D): NASA-selected technology that uses advanced robotics to print continuous carbon fiber in isogrid rib patterns for space applications.
Finite Element Analysis (FEA) Software: Tools like ANSYS or NASTRAN are used to simulate the structural loads (internal pressure vs. external atmosphere) on isogrid domes to ensure they can withstand Martian conditions.
Roboze One+400: A 3D printer specifically used in research for producing high-performance, lightweight isogrid structures.
Geodesic Dome Calculators: For the basic geometry of polyhedral domes, tools that calculate chord factors and strut lengths are used.
Applications on Mars:
3D Printed Shells: Research suggests using 3D-printable inner spherical shells and outer parabolic domes to protect habitats from the Martian climate.
Regolith Manipulation: Techniques like sintering or microwave melting of Martian regolith are planned for creating geodesic domes.
Structural Efficiency: Isogrid designs are used to minimize mass while maximizing pressure resistance, necessary for transporting materials from Earth or using indigenous resources.
Commonly Used Tools:
CAD: Autodesk Fusion 360, SolidWorks, CATIA.
Analysis: ANSYS, Abaqus, Altair HyperWorks.
Manufacturing: Specialized 3D printing software (slicers for robotic arms).
These tools are part of a broader approach to designing and testing Martian habitat structures, which must be both lightweight for transit and rigid enough to handle the 101 kPa pressure differential on Mars
#5 Re: Exploration to Settlement Creation » Ring Habitat on Mars Doughnut Torus » Yesterday 19:53:20
Isogrid technology, which involves creating rigid, lightweight triangular-stiffened structures, is a critical technique for designing space-hardened habitats and shells on Mars. While specific "plug-and-play" software labeled "Isogrid Maker for Mars" does not exist, aerospace and structural engineers use several advanced CAD and simulation tools to model these, often utilizing additive manufacturing (3D printing) for implementation.
Key Software and Modeling Techniques for Mars Domes:
Autodesk Fusion 360: Used for parametric modeling of isogrid structures. It allows engineers to create, test, and adapt the geometry of triangular ribs, which is critical for optimization.
Continuous Composites (CF3D): NASA-selected technology that uses advanced robotics to print continuous carbon fiber in isogrid rib patterns for space applications.
Finite Element Analysis (FEA) Software: Tools like ANSYS or NASTRAN are used to simulate the structural loads (internal pressure vs. external atmosphere) on isogrid domes to ensure they can withstand Martian conditions.
Roboze One+400: A 3D printer specifically used in research for producing high-performance, lightweight isogrid structures.
Geodesic Dome Calculators: For the basic geometry of polyhedral domes, tools that calculate chord factors and strut lengths are used.
Applications on Mars:
3D Printed Shells: Research suggests using 3D-printable inner spherical shells and outer parabolic domes to protect habitats from the Martian climate.
Regolith Manipulation: Techniques like sintering or microwave melting of Martian regolith are planned for creating geodesic domes.
Structural Efficiency: Isogrid designs are used to minimize mass while maximizing pressure resistance, necessary for transporting materials from Earth or using indigenous resources.
Commonly Used Tools:
CAD: Autodesk Fusion 360, SolidWorks, CATIA.
Analysis: ANSYS, Abaqus, Altair HyperWorks.
Manufacturing: Specialized 3D printing software (slicers for robotic arms).
These tools are part of a broader approach to designing and testing Martian habitat structures, which must be both lightweight for transit and rigid enough to handle the 101 kPa pressure differential on Mars
These are the quick google of software to use in a isogrid construction.
#6 Re: Science, Technology, and Astronomy » OpenFOAM » Yesterday 18:50:38
Sounds like progress.
Hopefully this might help
Calculating thrust in a Nuclear Thermal Propulsion (NTP) system—where hydrogen gas is heated by a reactor and expanded through a nozzle—requires determining the energy added to the hydrogen, the resulting mass flow rate, and the exit velocity.
Core Equations The fundamental equation for thrust (\(F\)) is:\(F=\.{m}\cdot v_{e}+(p_{e}-p_{a})A_{e}\)Where: \(\.{m}\) = mass flow rate (kg/s)\(v_{e}\) = exit velocity of exhaust (m/s)\(p_{e},p_{a}\) = exit pressure and ambient pressure (Pa)\(A_{e}\) = exit area of the nozzle (\(m^{2}\)) For a simplified estimation, if the nozzle is perfectly expanded (\(p_{e}=p_{a}\)), the formula simplifies to:\(F=\.{m}\cdot v_{e}\)
Step-by-Step Calculation Guide
1. Determine Mass Flow Rate (\(\.{m}\))You must know how much hydrogen is passing through the tube per second. If not given, this is determined by the input pressure, pipe diameter, and density.\(\.{m}=\rho \cdot A\cdot v\)(where \(\rho \) is density, \(A\) is cross-sectional area of tube, \(v\) is flow velocity)2. Calculate Exit Velocity (\(v_{e}\)) from WattageThe electrical power (wattage, \(P\)) or thermal power heats the hydrogen, converting electrical energy into kinetic energy (assuming high efficiency):\(P=\eta \cdot \frac{1}{2}\.{m}v_{e}^{2}\)Assuming an efficiency (\(\eta \)) of the system, rearranging for \(v_{e}\):\(v_{e}=\sqrt{\frac{2P}{\eta \.{m}}}\)Note: In actual NTP, power is thermal (MW) from a reactor, not just electric wattage.
3. Apply Tube Length (Thermal Efficiency & Pressure Drop) Heating (Length): Longer tubes allow higher hydrogen temperature (\(T_{exit}\)) up to material limits, increasing \(v_{e}\) and Specific Impulse (\(I_{sp}\)).Friction (Length): Longer tubes increase frictional pressure losses (\(-\Delta p\)), which can reduce exit velocity.Effect: The length must be optimized to maximize \(T_{exit}\) without excessive pressure drop. A longer tube generally increases the temperature and thus the thrust, provided the heat input continues along the length.
4. Final Thrust CalculationOnce \(v_{e}\) and \(\.{m}\) are determined, substitute them back into \(F=\.{m}\cdot v_{e}\). Key Parameters at NTP (Normal Temperature and Pressure) Propellant: Hydrogen (\(H_{2}\))Efficiency: Realistic NTP systems aim for high temperatures, often resulting in specific impulses (\(I_{sp}\)) around 800–900 seconds
Thrust Calculation (NTP) based on Power and Tube Dimensions To calculate the thrust (\(F\)) generated by a nuclear thermal propulsion (NTP) system using a hydrogen tube, you need to calculate the mass flow rate (\(\.{m}\)) based on the heating of the hydrogen (wattage) and determine the exit velocity (\(V_{e}\)) based on the tube length and operating temperature. Fundamental Equations
Thrust (F) = m_dot * V_eMass Flow Rate (m_dot) = P_in / ΔhStep-by-Step Calculation Formula Determine Exhaust Velocity (\(V_{e}\)):Assuming a simple, idealized expansion where the hydrogen is heated by a heat source:
V_e = sqrt( (2 * γ * R * T_chamber) / (γ - 1) )\(\gamma \) = Ratio of specific heats for Hydrogen (~1.4)\(R\) = Specific gas constant for Hydrogen (4124 J/kg·K)\(T_{c}\) = Chamber temperature (K)Determine Mass Flow Rate (\(\.{m}\)):
m_dot = W / (Cp * ΔT)\(W\) = Power/Wattage applied to the hydrogen (Watts)\(Cp\) = Specific heat capacity of Hydrogen (~14300 J/kg·K)\(\Delta T\) = Temperature increase of hydrogen (K)Calculate Thrust (\(F\)) in Newtons:
F = m_dot * V_eBBcode Formula for Inputting into Calculators
[b]Thrust (N)[/b] = (Watts / (14300 * ΔT)) * sqrt( (2 * 1.4 * 4124 * T_chamber) / (1.4 - 1) )Variables Definitions Wattage (\(W\)): Total power input into the hydrogen gas.Tube Length (\(L\)): Affects the residence time and heating efficiency, typically increasing \(\Delta T\) and \(T_{c}\).\(T_{c}\): Chamber temperature (K).\(\Delta T\): Temperature rise of hydrogen (K). Note: Hydrogen NTP systems typically achieve a specific impulse (Isp) of 850–1000 s. High thrust-to-weight ratios are possible compared to electric propulsion.
#7 Re: Exploration to Settlement Creation » Ring Habitat on Mars Doughnut Torus » Yesterday 18:17:57
Basalt sand processing is a multi-stage industrial process, rather than a single-step action. Because basalt is an extremely hard, high-density rock (\(2.8-3.0\text{\ g/cm}^{3}\)), processing focuses on efficient, multi-stage crushing, typically lasting for a few minutes per batch, but operating continuously. Basalt Sand Processing Time Chart Note: This represents the mechanical processing time of rock-to-sand in a typical industrial crusher.
Production Stage OperationEstimated Time (Duration)
1. FeedingVibrating Feeder (removes debris)Continuous (immediate)
2. Primary CrushingJaw Crusher (\(>300\text{mm}\rightarrow <50\text{mm}\))Seconds to Minutes
3. Secondary/FineCone Crusher (\(50\text{mm}\rightarrow \text{smaller}\))Seconds to Minutes
4. Sand MakingVSI Crusher (shapes and grinds)Seconds to Minutes
5. ScreeningSeparating particle sizesContinuous (concurrent)
6. Washing/DewateringWashing & Drying (if wet process)10–30+ minutes
Total Cycle TimeRaw Rock \(\rightarrow \) Finished Sand\(<1\text{\ hour\ per\ batch}\)
Key Processing Steps & Considerations
Crushing Technology: Due to the hardness of basalt, laminated principle crushing equipment is recommended to minimize wear and tear.
Production Volume: Large-scale, high-capacity plants (e.g., 350-400 TPH) are common for basalt, focusing on creating construction aggregate, asphalt material, and manufactured sand.
Dry vs. Wet Process: Dry, vertical shaft impact (VSI) crushers are often used to create a uniform particle size, while wet processes are used to wash and remove fine dust.
Performance Metrics: The process aims for high efficiency, with a high crushing rate and low operational costs
[table]
[tr][td][b]Process Step[/b][/td][td][b]Description[/b][/td][td][b]Estimated Time[/b][/td][/tr]
[tr][td]1. Quarrying/Mining[/td][td]Extracting raw basalt rock[/td][td]1-3 Days[/td][/tr]
[tr][td]2. Primary Crushing[/td][td]Jaw crusher reduces rock size[/td][td]2-5 Hours[/td][/tr]
[tr][td]3. Secondary/Fine Crushing[/td][td]Cone crusher/Impact crusher[/td][td]3-6 Hours[/td][/tr]
[tr][td]4. Screening[/td][td]Separating by particle size[/td][td]1-2 Hours[/td][/tr]
[tr][td]5. Washing/Drying[/td][td]Removing fines/Moisture control[/td][td]4-12 Hours (varies by drying method)[/td][/tr]
[tr][td]6. Bagging/Shipping[/td][td]Packaging and dispatch[/td][td]1-2 Days[/td][/tr]
[/table] Typical Production Metrics
Production Capability: 154,000 T/month (system capacity).
Throughput: 30–700+ t/h (depending on line size).
Basalt Hardness: High (139-185 MPa) requires heavy duty equipment.
#8 Re: Exploration to Settlement Creation » KBD512 Biosphere structure of cast basalt » Yesterday 18:16:52
Basalt sand processing is a multi-stage industrial process, rather than a single-step action. Because basalt is an extremely hard, high-density rock (\(2.8-3.0\text{\ g/cm}^{3}\)), processing focuses on efficient, multi-stage crushing, typically lasting for a few minutes per batch, but operating continuously. Basalt Sand Processing Time Chart Note: This represents the mechanical processing time of rock-to-sand in a typical industrial crusher.
Production Stage OperationEstimated Time (Duration)
1. FeedingVibrating Feeder (removes debris)Continuous (immediate)
2. Primary CrushingJaw Crusher (\(>300\text{mm}\rightarrow <50\text{mm}\))Seconds to Minutes
3. Secondary/FineCone Crusher (\(50\text{mm}\rightarrow \text{smaller}\))Seconds to Minutes
4. Sand MakingVSI Crusher (shapes and grinds)Seconds to Minutes
5. ScreeningSeparating particle sizesContinuous (concurrent)
6. Washing/DewateringWashing & Drying (if wet process)10–30+ minutes
Total Cycle TimeRaw Rock \(\rightarrow \) Finished Sand\(<1\text{\ hour\ per\ batch}\)
Key Processing Steps & Considerations
Crushing Technology: Due to the hardness of basalt, laminated principle crushing equipment is recommended to minimize wear and tear.
Production Volume: Large-scale, high-capacity plants (e.g., 350-400 TPH) are common for basalt, focusing on creating construction aggregate, asphalt material, and manufactured sand.
Dry vs. Wet Process: Dry, vertical shaft impact (VSI) crushers are often used to create a uniform particle size, while wet processes are used to wash and remove fine dust.
Performance Metrics: The process aims for high efficiency, with a high crushing rate and low operational costs
[table]
[tr][td][b]Process Step[/b][/td][td][b]Description[/b][/td][td][b]Estimated Time[/b][/td][/tr]
[tr][td]1. Quarrying/Mining[/td][td]Extracting raw basalt rock[/td][td]1-3 Days[/td][/tr]
[tr][td]2. Primary Crushing[/td][td]Jaw crusher reduces rock size[/td][td]2-5 Hours[/td][/tr]
[tr][td]3. Secondary/Fine Crushing[/td][td]Cone crusher/Impact crusher[/td][td]3-6 Hours[/td][/tr]
[tr][td]4. Screening[/td][td]Separating by particle size[/td][td]1-2 Hours[/td][/tr]
[tr][td]5. Washing/Drying[/td][td]Removing fines/Moisture control[/td][td]4-12 Hours (varies by drying method)[/td][/tr]
[tr][td]6. Bagging/Shipping[/td][td]Packaging and dispatch[/td][td]1-2 Days[/td][/tr]
[/table] Typical Production Metrics
Production Capability: 154,000 T/month (system capacity).
Throughput: 30–700+ t/h (depending on line size).
Basalt Hardness: High (139-185 MPa) requires heavy duty equipment.
#9 Re: Meta New Mars » Housekeeping » Yesterday 17:47:16
Rather than shape more information of Basalt forming blocks from hard rock or from sands if site present as I included in the topics.
As 5 days plus for single blocks means we are not building very much for each processed batch.
#10 Re: Not So Free Chat » Greenland » Yesterday 17:44:42
If all bases come home, that means we are headed to be isolationism once more and we know what happened after we were a nation on that course what happened.
National isolationism is a foreign policy where a country avoids political, military, and sometimes economic alliances and involvement with other nations, focusing instead on domestic issues and self-reliance, exemplified historically by the U.S. under Washington's Farewell Address, aiming for neutrality and avoiding "foreign entanglements". While often seeking economic engagement, it emphasizes non-intervention in foreign wars and disputes, though it can manifest through trade restrictions (protectionism) or diplomatic detachment.
Key Characteristics
Avoidance of Alliances: Refusal to join binding military pacts or international agreements that might draw the nation into foreign conflicts.
Non-Intervention: Staying out of other nations' wars and political disputes, a concept rooted in George Washington's warning.
Self-Reliance: Focusing national efforts on internal development and security.
Economic Policies: Can include protectionist tariffs to shield domestic industries from foreign competition.
Historical Example: United States
Founding Era: Early U.S. policy, guided by Washington, sought commercial ties but political detachment from Europe.
19th Century: Maintained political isolation while expanding territory.
Interwar Period (1930s): Strong isolationist sentiment, reinforced by the Great Depression and WWI trauma, leading to Neutrality Acts.
End of Era: The attack on Pearl Harbor in 1941 effectively ended this period of broad isolationism
#11 Re: Science, Technology, and Astronomy » Natural hydrogen (known as white hydrogen or gold hydrogen) » Yesterday 16:01:26
Researchers discover massive hydrogen system beneath the Pacific Ocean
Far below the surface of the western Pacific Ocean, scientists have uncovered a geological system that reshapes how you may think about Earth’s hidden energy potential. Deep beneath thousands of meters of water, a massive network of ancient underground structures points to the presence of large amounts of natural hydrogen formed deep within the planet.
Hydrogen is the most common element in the solar system and a promising clean fuel. Yet on Earth, large natural stores have been difficult to find. Most hydrogen used today is produced through industrial methods that rely on fossil fuels. This new discovery suggests the planet itself may generate far more hydrogen than once believed.
Researchers from the Institute of Oceanology of the Chinese Academy of Sciences, working with international collaborators, identified the system on the east Caroline Plate, west of the Mussau Trench. The team analyzed a vast group of underground formations that show clear signs of intense hydrogen driven activity in the distant past.
The Mussau Trench is not active today. It began forming about 25 million years ago and has long since stopped moving. Despite this quiet history, the seafloor nearby holds dramatic clues of powerful forces that once shaped the region.
The scientists discovered a cluster of huge cylindrical structures known as breccia pipes. They named the formation the Kunlun pipe swarm. Each pipe measures between 450 and 1,800 meters wide, making them some of the largest known structures of their kind beneath the ocean.
These pipes are filled with broken rock fragments, showing signs of violent formation. Their steep walls and layered shapes resemble kimberlite pipes found on land, which are created by explosive geological events. Several smaller bowl shaped craters sit within the larger pipes, suggesting repeated bursts of energy over time.
Based on energy estimates, forming structures this large would require explosive force equal to millions of tons of TNT. Scientists believe hydrogen provided that power.
Traces of a Hydrogen Driven System
The team also found clear evidence of hydrothermal activity tied to hydrogen rich fluids. Hydrothermal fluids are hot mixtures of water and minerals that rise through cracks in the Earth’s crust. In the Kunlun pipes, these fluids once sprayed through tiny channels along pipe walls and through cracks in rock piles.Many of the rocks show yellowish coloring, likely caused by microbial mats. These mats are layers of microorganisms that thrive in chemically rich environments. Their presence suggests the system supported life fueled by chemical energy rather than sunlight.
Hydrothermal life was not limited to microbes. Researchers observed entire biological communities near the pipes. Scorpionfish, which sit at the top of the local food chain, were common. Because predators need a large food supply, scientists believe extensive microbial growth exists within the rock piles at the base of the pipes, even if much of it remains hidden.
Seismic Signals Point to Gas Movement
The discovery did not rely on visual evidence alone. Over 28 days, researchers recorded more than 800 small earthquakes along a 150 kilometer stretch crossing the trench. These short seismic events point to ongoing gas movement beneath the seafloor.Chemical testing of hydrothermal fluids added another clue. Nitrogen isotope analysis showed a strong atmospheric gas component, meaning gases from the surface likely mixed with hydrogen rising from deep within the Earth.
Unlike previously known hydrogen rich systems, this one sits far from active plate boundaries. Most similar discoveries occurred near spreading ridges or active faults, such as the well known Lost City hydrothermal field. Kunlun lies about 80 kilometers from active plate margins, showing that hydrogen formation does not require ongoing tectonic motion.
Why Hydrogen Fits the Evidence
Hydrogen can store and release enormous energy under pressure. Scientists calculated that one ton of hydrogen expanding rapidly from deep pressure levels to seafloor pressure could release energy equal to 0.21 tons of TNT. If hydrogen reacted with oxygen, the energy release would be even greater, about 150 times stronger than simple expansion.Such power matches what would be needed to blast out pipes of this scale. According to Prof. XIAO Yuanyuan, first author of the study, the results suggest a vast amount of hydrogen formed deep in the oceanic mantle and later escaped upward. “It could be economically mineable in the future,” XIAO said.
The hydrogen likely formed through reactions between seawater and mantle rocks, a process that produces both heat and hydrogen gas. Over time, pressure built until sudden releases carved out the pipes now seen on the seafloor.
Rethinking Earth’s Hidden Resources
This discovery changes how scientists view Earth’s natural hydrogen cycle. It shows that large hydrogen systems can form far from volcanic hotspots and remain hidden for millions of years. It also raises questions about how many similar systems exist elsewhere beneath the oceans.For now, the Kunlun pipe swarm offers a rare window into deep Earth chemistry. It also shows how powerful chemical reactions can shape geology, ecosystems, and possibly future energy options.
Practical Implications of the Research
This research expands understanding of how hydrogen forms and moves inside Earth. It may guide future studies searching for natural hydrogen resources on land and under the sea.While deep ocean mining is not currently practical, the findings could influence long term clean energy research.
Understanding these systems also helps scientists better model Earth’s geology, gas cycles, and deep life ecosystems, benefiting both environmental science and future energy planning.
Research findings are available online in the journal Science Advances.
#12 Re: Terraformation » Landmaking » Yesterday 15:51:45
Biosphere 2 shape with KBD512 Biosphere structure of cast basalt
but the reality was They locked humans in a fake Earth for 2 years and the experiment imploded
In the early 1990s, eight people agreed to vanish from the world and live for two years inside a sealed glass habitat in the Arizona desert, a kind of fake Earth built to see whether humans could survive in a closed ecosystem. The project, called Biosphere 2, was supposed to be a dress rehearsal for space colonies and a bold test of whether we could bottle an entire planet. Instead, the grand experiment unraveled in a tangle of oxygen crashes, food shortages, and human conflict that still shapes how scientists think about living off-world.
Three decades later, the story of that first mission reads less like a clean scientific trial and more like a pressure cooker drama about what happens when you try to compress Earth into a box and lock people inside. The failures were real and sometimes dangerous, but so were the lessons about climate, engineering, and human psychology that emerged from the implosion.
#13 Re: Human missions » Why Artemis is “better” than Apollo. » Yesterday 12:26:23
Artemis II: NASA's mega Moon rocket arrives at launch pad
Nasa's mega rocket has been moved to the launch pad in Cape Canaveral, Florida, as the final preparations get underway for the first crewed mission to the Moon in more than 50 years.
Over almost 12 hours, the 98m-tall Space Launch System was carried vertically from the Vehicle Assembly Building on the 4-mile (6.5km) journey to the pad.
Now it is in position, the final tests, checks - and a dress rehearsal - will take place, before the go-ahead is given for the 10-day Artemis II mission that will see four astronauts travel around the Moon.
Nasa says the earliest the rocket can blast off is 6 February, but there are also more launch windows later that month, as well as in March and April.
The rocket began moving at 07:04 local time (12:04 GMT) and arrived at Launch Pad 39B at the Kennedy Space Center at 18:41 local time (23:42 GMT).
The rocket was carried by a huge machine called a crawler-transporter, travelling at a top speed of 0.82 mph (1.3 km/h) as it trundled along. Live coverage captured the slow-moving spectacle.
Nasa said the rocket will be prepared over the next few days for what it calls a "wet dress rehearsal" - a test for fuel operations and countdown procedures.
The Artemis II crew - Nasa's Reid Wiseman, Victor Glover and Christina Koch and Canadian astronaut Jeremy Hansen - were at the Kennedy Space Center watching the rocket as it was moved.
In just a few weeks, the four astronauts will be strapped into a spacecraft, perched on the top of the rocket, ready to blast off to the Moon.
It will be the first crewed mission to the Moon since Apollo 17 landed on its surface in December 1972.
Nasa said the mission could take its astronauts further into space that anyone has been before.
Artemis II is not scheduled to land on the Moon, but will instead lay the groundwork for a future lunar landing led by the Artemis III mission.
Nasa said the launch of Artemis III will take place "no earlier than" 2027. But, experts believe 2028 is the earliest possible date.
Koch said it was an amazing feeling to see the rocket.
"Astronauts are the calmest people on launch day. And I think... it feels that way because we're just so ready to fulfil the mission that we came here to do, that we've trained to do," she said.
Hansen said he hoped the mission would inspire the world.
"The Moon is something that I've taken for granted. I've looked at it my whole life, but then you just glance at it and glance away," he said.
"But now I've been staring at it a lot more, and I think others will be joining us and staring at the Moon a lot more as there will be humans flying around the far side and that is just good for humanity."
Before Artemis II heads to the Moon, the first two days of their mission will be spent in orbit around the Earth.
"We're going to be going into an orbit almost right away that is 40,000 miles out - like a fifth of the way of the Moon," Koch told BBC News.
"We will have the Earth out the window as a single ball, something none of us have seen in that perspective.
"And then we're going to travel a quarter of a million miles away… we're going to do a lot of science and operations along the way."
While they fly around the far side of the Moon, the crew will have three hours dedicated to lunar observation - to gaze, take images and to study its geology, which will help plan and prepare for a future landing at the Moon's south pole.
A key part of the Orion spacecraft that the astronauts will be flying in was made in Bremen in Germany.
The European Service Module, which sits behind the crew capsule, is the European Space Agency's contribution to the mission and has been built by Airbus.
"The European Service Module is so important - we basically can't get to the Moon without it," says Sian Cleaver, a spacecraft engineer at Airbus.
"It provides the propulsion that Orion needs to get us to the Moon."
Its large solar arrays will generate all the electrical power for the craft, she adds.
"We've also got these big tanks full of oxygen and nitrogen, which are mixed to make air, and also water, so that we can provide everything that the astronauts need in the crew module to keep them alive on their journey."
Inside their cleanroom, the team is busy building more modules for future Artemis missions. Each one takes about 18 months to put together but has taken thousands of engineering hours to design. Everything on board has to work perfectly.
"We've got to get those astronauts to the Moon and then back again, completely safely," says Cleaver.
With the rocket now on launchpad 39B, the Artemis team is working around the clock to get it ready for lift off.
The mission has already faced years of delays, and Nasa is under pressure to get the astronauts on their way as soon as possible. However, the US space agency said it would not compromise on safety.
John Honeycutt, chair of the Artemis mission management team, said: "I've got one job, and it's the safe return of Reid and Victor and Christina and Jeremy.
"We're going to fly when we're ready... crew safety is going to be our number one priority."
#14 Re: Exploration to Settlement Creation » WIKI Project Designing for Mars » Yesterday 12:08:54
more dummy pages
#15 Re: Exploration to Settlement Creation » WIKI Project Designing for Mars » Yesterday 12:08:47
cooling or dehumidiation
For a structure with a 200 m (656 ft) diameter and 120 m (394 ft) tall parabolic dome, standard High-Volume, Low-Speed (HVLS) ceiling fans, typically with diameters up to 7.3 meters (24 feet), would be used in a calculated array to provide effective air circulation. Multiple fans, rather than a single massive fan, are required due to the immense size of the space.
Step 1: Calculate the Floor Area and Assess Fan Coverage The floor area of the dome is a circle with a radius of 100 m:\(\text{Area}=\pi \times \text{radius}^{2}=\pi \times 100^{2}\approx 31,416\,\text{m}^{2}\,(338,166\,\text{ft}^{2})\)A single large HVLS fan (e.g., 7.3 m diameter) typically covers between 900 and 1,500 square meters. For cooling purposes, the coverage area is roughly five times the fan's diameter for large-blade fans, but for destratification (air mixing in very high spaces), it can be up to ten times.
Step 2: Determine the Number and Placement of Fans Given the vast area, an array of fans is necessary. The general guideline is to space fans a distance equal to at least one fan diameter apart, or up to three times the diameter depending on the manufacturer and application. For consistent coverage, a grid pattern is ideal. For such a massive, open space, consulting with an HVLS expert for a custom layout drawing is crucial. The number of 7.3-meter (24-foot) fans could range from 21 to over 30 to cover the entire area effectively, depending on specific airflow requirements and building obstructions.
Step 3: Consider Ceiling Height and Fan Mounting The 120 m (394 ft) ceiling is extremely high. While fans perform well when mounted between 6 and 12 meters (20 to 40 feet) above the floor, longer downrods might be needed to position the fans within the occupied zone for optimal air movement. The fans must also maintain safe clearance from the floor (at least 3 m or 10 ft) and other structural elements.
Answer: For a parabolic dome ceiling with a 200 m diameter and 120 m height, multiple HVLS fans with diameters typically ranging from 6.1 meters to 7.3 meters (20 to 24 feet) would be required. The exact number and strategic placement of fans, likely exceeding two dozen units, should be determined through a professional airflow study to ensure uniform air circulation and temperature control
Commercial 7m (7-meter) fans refer to large industrial fans, often HVLS (High-Volume, Low-Speed) ceiling fans, used for cooling vast spaces like warehouses, factories, malls, and arenas, providing massive airflow (measured in CFM) for comfort and energy efficiency in huge commercial areas. You'll find them as massive ceiling units or powerful pedestal/wall-mounted fans designed for serious air movement, not typical home use, with high CFM ratings (thousands) for effective cooling.
Key Characteristics:
Size & Type: Look for HVLS fans (often 7 feet or more in diameter) or large pedestal/wall fans, not standard residential ceiling fans.
Airflow (CFM): Measured in Cubic Feet per Minute; higher CFM means more air moved, crucial for large spaces (e.g., 7000+ CFM is common).
Applications: Warehouses, factories, gyms, shopping centers, agricultural buildings, and large event spaces.
Benefits: Better air circulation, reduced heat, improved comfort, and energy savings over traditional AC in large buildings.
Where to Find Them:
Home Improvement Stores: The Home Depot offers large industrial ceiling fans.
Online Marketplaces: Alibaba.com has many manufacturers for 7m industrial fans.
Specialty Retailers: Amazon.com (for large pedestal/wall fans) and industrial fan suppliers.
When searching, use terms like "HVLS fan," "industrial ceiling fan," "large commercial fan," or specify CFM and diameter (like 7ft or 7m) for best results
#16 Re: Exploration to Settlement Creation » WIKI Project Designing for Mars » Yesterday 12:08:40
more dummy pages
#17 Re: Exploration to Settlement Creation » WIKI Project Designing for Mars » Yesterday 12:08:24
Colony or settlement sized
Designing a Mars water system for a crew of 4-6 (initial) to dozens (colony) relies on In-Situ Resource Utilization (ISRU), primarily extracting water from Martian soil/ice via heating or microwave drilling, supplemented by high-efficiency closed-loop recycling of hygiene/wastewater, plus atmospheric water harvesting (like MARRS), all integrated with habitats (MHUs) and power (solar/nuclear), ensuring redundancy for survival and growth.
1. Water Sources & Extraction (ISRU)
Subsurface Ice/Hydrated Minerals: The main source; systems heat regolith (200-500°C) or use microwave energy down boreholes to vaporize water, then collect and condense it.
Atmospheric Water: Systems like MARRS (Mars Atmospheric Resource Recovery System) capture water vapor from the thin Martian atmosphere.
2. Water Processing & Recycling (Life Support)
ECLSS (Environmental Control and Life Support Systems): Highly reliable systems (similar to ISS) to recycle water from urine, humidity, and hygiene.
Bioregenerative Systems: Using algae or plants (in greenhouses/hydroponics) to further purify water and produce food, reducing Earth dependence.
3. System Design for Different Crew Sizes
Early Missions (4-6 crew): Focus on robust, high-reliability closed-loop systems with significant storage (1000+ days' supply) and initial ISRU capability.
Colony (Growing to 20+): Requires large-scale, scalable ISRU plants, modular habitats (MHUs) with extendable capacity, and robust power generation (solar/nuclear).
4. Key Components & Concepts
ISRU Hardware: Mobile units (like Honeybee Robotics' MISWE) for exploration and extraction.
Habitat Modules (MHUs): Inflatable structures with integrated water processing, living areas, and crop growth zones.
Power: Thin-film solar arrays or small nuclear reactors to power extraction and life support.
Redundancy: Critical for survival; backup storage, parallel systems, and emergency escape routes within habitats.
5. Water Needs Estimation
Baseline: Around 0.6-0.7 kg/person/hour (consumption, hygiene, plant growth) in a gravity environment, with high reclamation.
Plants: Require additional water (approx. 0.003 kg/hr/person) not easily reclaimed.
Example Design Framework (for a growing colony)
Initial Landing: Crew of 4-6 with pre-deployed ISRU hardware and life support units.
Expansion (Year 2+): Increase crew (6, 12, 24 per mission) using new missions, deploy larger ISRU facilities, establish larger crop areas, and build more habitat clusters.
ISRU Integration: Automated systems extract water, feed it to storage, processing units, and greenhouses, ensuring continuous supply
#18 Re: Exploration to Settlement Creation » WIKI Project Designing for Mars » Yesterday 12:07:27
Exploration sized
Designing a Mars water production system for a crew of 4-6 involves a multi-pronged approach: In-Situ Resource Utilization (ISRU) from Martian soil/ice, highly efficient water recycling (up to 98%+ on ISS) for transit, and robust storage/treatment systems, requiring advanced drills/miners, Sabatier reactors, electrolysis units, filtration (RO/Forward Osmosis), and storage tanks (FRP/PEX) with nanotechnology for a 1.5-2.5 year mission to meet hygiene, metabolic, and fuel needs. Crew size (often 4-6) dictates scale, with larger crews needing more redundancy and capacity, but fewer crew (e.g., 3) significantly reduces mass/cost, influencing system design. Key System Components & Design Principles Water Sourcing (ISRU):Regolith Extraction: Drills/heaters (like Mars Ice Drill concept) to extract water vapor from Martian soil (regolith) or subsurface ice.Atmospheric Extraction: Condensing atmospheric water vapor, though less direct than soil extraction.Chemical Conversion (Sabatier/Electrolysis): Using imported hydrogen and atmospheric \(\text{CO}_{2}\) to make methane fuel and water (\(\text{H}_{2}\text{O}\)), then electrolyzing water for breathing oxygen/rocket oxidizer.Water Production & Processing:Water Recovery System (WRS): Similar to ISS, recycling urine, humidity condensate, hygiene water with high efficiency (near 98%).Treatment: Reverse Osmosis (RO), Forward Osmosis (FO), distillation, and advanced filtration for purification.Storage: Lightweight tanks (Fiber-Reinforced Plastic - FRP, crosslinked Polyethylene - PEX) with leak detection, heating to prevent freezing.Life Support Integration:Metabolic Water: Generated from food/fuel (like the movie The Martian's concept using rocket fuel, though ISRU is preferred).Hygiene Water: Separate loop with efficient recovery and reuse. Crew Size Considerations (4-6 Astronauts) 6 Crew (Conjunction Class Mission): Longer stays (18 months surface), higher demand for water, requires larger ISRU units, more robust recycling, significant water storage redundancy.4 Crew (Transit/Surface): Lower overall demand, potentially simpler systems, but still needs high reliability for long durations (400-500 days transit + surface stay).Smaller Crew (3): Significantly reduces mass/cost/complexity, making larger ISRU systems more feasible or requiring less overall capacity, but fewer hands for maintenance. Mission Profile Example (6 Crew, ~2.5 Years Total) Transit (9-12 months): Relies heavily on recycled water, backup supplies (30+ metric tons if all water carried).Surface Stay (18 months): ISRU becomes critical for sustaining hygiene, metabolic needs, and propellant production for return.Key Design Goal: Minimize water mass from Earth; maximize ISRU & recycling to make the mission feasibl
#19 Re: Exploration to Settlement Creation » WIKI Project Designing for Mars » Yesterday 11:57:26
project design to produce water on mars system for science mission size
Designing a Mars water production system for science missions involves extracting subsurface ice or hydrated minerals, processing them (heating/microwave), and collecting the vapor, using methods like drills (Coiled Tubing), heated regolith extraction (C.R.A.T.E.R.), or Rodriguez Wells, focusing on reliability, low mass, power efficiency for tasks like life support (ISRU) and propellant, with key components including drills, heaters, condensers, storage, and potentially atmospheric processors for oxygen/methane.
Core Concepts & Technologies
In-Situ Resource Utilization (ISRU): The overarching goal is using local Martian resources (water ice, atmospheric CO2) to create needed consumables (water, oxygen, methane fuel).
Extraction Methods:
Drilling: Using drills (like the Mars Ice Drill or Coiled Tubing) to reach buried ice, potentially melting it in situ.
Regolith Heating: Heating Martian soil (regolith) to release bound water molecules (e.g., 200-500°C).
Rodriguez Well (Rodwell): A method using a well to access large subsurface ice deposits, especially glacier-like forms.
Processing & Collection:
Microwave Heating: Efficiently freeing water from soil.
Condensers: Cooling water vapor to collect liquid water.
Storage: Tanks for storing extracted water.
Atmospheric Processing (for oxygen/methane): Using the Sabatier process (CO2 + H2 → CH4 + H2O) to make fuel, creating water as a byproduct.
System Design for Science Missions (Scalable)
Targeting: Use orbital data to find shallow subsurface ice or hydrated minerals, crucial for accessibility.
Excavation/Drilling Unit: A robust, potentially semi-autonomous system (e.g., drill with air/water jets) to reach the ice/hydrated material.
Processing Unit:
Heating Element: For regolith (microwaves/resistive heating) or sublimating ice.
Separation/Condensation: Capturing water vapor.
Collection & Storage: A reliable system to meter and store the water in tanks, potentially with internal heating/cooling loops.
Power & Control: Solar/RTG power, autonomous controls for simple operations, and telemetry for remote monitoring.
Integration (Optional): Link to a life support system (like CHRSy) for crewed missions or propellant production.
Example Project Elements (Student/Small Scale)
C.R.A.T.E.R. System (Colorado School of Mines): A conveyor belt system to feed Martian soil into a microwave-heated casing for water extraction.
Mars Ice Drill (FAU): A drill to penetrate ice, heat it, and pump water to the surface for collection
Designing a Mars water system for a science mission (e.g., 3-6 crew) involves In-Situ Resource Utilization (ISRU) like extracting subsurface ice (drilling/melting) or atmospheric vapor, combining with water recycling (ISS-style) for reliability, and using systems like Sabatier reactors for propellant/oxygen production, all needing redundancy and significant power (160kW+) for a ~1.5 yr stay, balancing mass/cost with crew needs for drinking, hygiene, science, and crucial life support. Key Design Components & Technologies Water Sourcing (ISRU)Subsurface Ice Extraction: Drilling (e.g., Coiled Tubing method) to access buried ice, followed by melting.Atmospheric Extraction: Capturing water vapor from the Martian atmosphere.Waste & Recycling: Advanced systems to recover water from urine, humidity, and hygiene, similar to ISS but with higher reliability for Mars.Water Processing & StoragePurification: Filtration, reverse osmosis, distillation, and UV treatment.Storage: Durable tanks (FRP, PEX) with anti-freeze/heating to prevent freezing, plus distribution piping.Water for Propulsion & Life SupportSabatier Reactor: Uses imported Hydrogen (\(H_{2}\)) and Martian Carbon Dioxide (\(CO_{2}\)) to create methane (\(CH_{4}\)) fuel and water (\(H_{2}O\)).Electrolysis: Splits water into Hydrogen and Oxygen, providing breathable air and rocket propellant (for ascent/return). Crew Size & System Implications Crew Size (e.g., 3-6): Impacts total water needed (drinking, hygiene, food prep, science), influencing habitat volume, water processing capacity, and ISRU system scale.Mass & Cost: ISRU dramatically cuts Earth-launched mass by using local resources, making missions feasible and more autonomous.Reliability: Higher redundancy and robust systems are critical due to the long travel time and inability to quickly resupply if systems fail. Example Mission Scenario (6 Crew) Pre-deployed Cargo: Habitat, ISRU plant, Descent/Ascent Vehicle (DAV) sent ahead.Crew Transit: Transported in a separate vehicle, potentially using water electrolysis for propulsion.Surface Operations: ISRU system extracts water, processes it, and stores it; water is used for life support and creating propellant for return. Key Considerations for Science Missions Power: Significant power (160kW+) needed for ISRU, life support, and thermal control.Science Payload: Water use for scientific experiments (e.g., hydroponics, sample processing) must be budgeted.Planetary Protection: Strict protocols for handling potential Martian microbes
Water Extraction from Martian Soil
The topic we have
ISRU Technology Development for Extraction of Water from the Mars Surface
#20 Re: Exploration to Settlement Creation » WIKI Project Designing for Mars » Yesterday 11:57:14
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#21 Re: Exploration to Settlement Creation » WIKI Project Designing for Mars » Yesterday 11:57:03
project design to produce food for mars crew sizes during colony or settlement missions
Designing a Mars food system involves closed-loop, resource-efficient bioregenerative systems, integrating high-yield crops (wheat, soy, sweet potatoes), microbial/algae protein, potentially cultured meats, and fungi, within vertical farms using Martian regolith amendments and recycled water, requiring minimal external resupply for large settlements, focusing on nutrition, caloric density, minimal waste, and crew effort, as highlighted by NASA's Deep Space Food Challenges.
Core Components of a Martian Food System
Crop Production:
Vertical Farms: Soil-less, hydroponic/aeroponic systems in controlled environments (modules) to maximize space and nutrient delivery.
Suitable Crops: High-calorie staples like wheat, corn, soybeans, peanuts, and sweet potatoes.
Soil Enhancement: Using Martian regolith (soil) amended with organic matter from composted waste, fungi, and worms for long-term soil building.
Protein Sources:
Microbial/Algae: Cultivating bacteria, fungi (mushrooms), and algae for nutrient-rich protein.
Insects/Cultured Meat: Crickets or lab-grown meat could supplement diets, reducing space/resource needs compared to traditional livestock.
Resource Management (Closed-Loop):
Water Recycling: Essential for all life support, including hydroponics.
Waste Management: Incineration or biological digestion (anaerobic) to recover nutrients and water, minimizing stored waste.
Atmosphere Control: Regulating CO2, temperature, humidity within grow modules.
System Integration:
Modular Design: Interconnected modules for different functions (growing, processing, living).
Automation & AI: To manage complex growing conditions and minimize crew labor.
Energy Efficiency: Critical for lighting and environmental control, potentially using solar or nuclear power.
Design Considerations for Scale
Initial Crews (Small Scale): Focus on high-efficiency, pre-packaged food supplemented by early, compact growing systems.
Settlement Growth (Large Scale): Shift to large-scale, self-sustaining systems, modeling needs for potentially thousands or millions, incorporating tunnels for space.
Nutritional Completeness: The system must provide 100% of required nutrients, not just calories, for long-duration health.
Key Technologies & Challenges
Genetic Engineering: Modifying plants for higher productivity and CO2 consumption.
3D Bioprinting: For creating complex food structures.
Sustainability: Achieving food independence from Earth, a significant long-term goal.
This project design concept integrates ideas from NASA's challenges and scientific modeling, emphasizing bioregenerative life support for sustainable Martian settlements.
#22 Re: Meta New Mars » Housekeeping » Yesterday 11:39:28
A Borehole Thermal Energy Storage (BTES) system, involving a series of U-tube pipes connected in a closed-loop and drilled 50–200m deep, would be necessary to transfer heat between the habitat and the deep ground.
The ground loop is dug and the filled where you would like it so if you want the loop in the ziggurat structure it could be done on even beneath the entire structure the loop does not care where it is so long as its at a given depth to become a stable location of temperature gradient.
As far as something to hold internal items that are not load baring for the structure it depends on how much materials remains after the dome is built.
I gave you in the topic two different methods to get what we need one that costs power energy and one that uses waste radiated heating with less energy being used to achieve the goal.
The heat pump also give cooling while a separate cooling loop is required to supplement the waste heat system which increases resources that might not be present.
#23 Re: Home improvements » Heat Pump - Heat Pumps » Yesterday 09:16:35
Ground heat pumps (geothermal) are a promising concept for Mars settlements, using the relatively stable underground temperature of the regolith for efficient heating and cooling, supplementing solar/nuclear power, and can even be reversed to manage waste heat, though deep drilling for consistent heat is challenging initially, requiring significant infrastructure. While NASA currently lacks deep Mars data, shallow systems could exploit the day-night temperature swings, and larger, deep-drilled systems offer long-term potential for large-scale colonies, making them key for sustainable power and thermal management.
How it works on Mars
Heating: In winter or cold periods, heat is extracted from the ground (regolith) and transferred into habitats.
Cooling: In summer or during peak operation, the system can reverse, dumping waste heat into the ground to cool habitats.
Shallow vs. Deep: Shallow systems use the day-night temperature difference, while deeper systems tap into the planet's consistent internal heat, similar to Earth's geothermal systems.
Benefits for Mars settlements
Efficiency: Heat pumps are much more efficient than electrical resistance heating, using less power for the same thermal effect, according to a presentation at AAPG 2017.
Reduced Transport: Uses local resources (regolith) and electricity, reducing reliance on fuel imports from Earth, notes the AAPG presentation.
Waste Heat Management: Effectively uses waste heat from industrial processes or power generation, as discussed in a Reddit thread.
Reliability: Less affected by Martian dust storms that hinder solar power, as noted on the NASA Spaceflight Forum.
Challenges
Drilling: Deep drilling for consistent geothermal sources is technologically challenging and expensive for early colonies, though feasible for later-stage settlements, as pointed out in a Quora discussion.
Data Gap: NASA currently has limited data on Mars's internal thermal gradients, notes a NASA document.
Future potential
Geothermal is considered a vital long-term solution for large, self-sustaining Martian societies, potentially alongside solar and nuclear power, states a Utah FORGE article.
A ground heat pump system for a 200-meter diameter, 120-meter tall Mars settlement dome would serve primarily as a high-capacity, long-term thermal management system rather than a standard HVAC unit, leveraging the high insulating capacity of Martian regolith to maintain comfortable internal temperatures (approx. 20°C) against an average ambient temperature of -63°C. Due to the immense heat loss to the cold Mars environment, this system would likely require over 1 MW of heating power, with the ground acting as both a heat source and a heat sink.
Key Technical Considerations
Heat Loss and Power Needs: A 200m dome (volume ~83 million m³) has massive surface area, requiring substantial energy to prevent heat loss, with estimates exceeding 100 MW of heating during, for instance, a cold winter night.
Regolith as Insulation: Martian regolith is a poor thermal conductor (approx. 0.039 W/(m·K)), which is beneficial, as it acts as a natural insulator when used to cover or bury portions of the dome.
Subsurface Temperatures: While surface temperatures fluctuate wildly (-153°C to 20°C), deep underground temperatures on Mars are generally below the freezing point of water, requiring the heat pump to manage a large, constant temperature differential.
System Design (BTES): A Borehole Thermal Energy Storage (BTES) system, involving a series of U-tube pipes connected in a closed-loop and drilled 50–200m deep, would be necessary to transfer heat between the habitat and the deep ground.
Operational Strategy
Thermal Regulation: The system would likely operate as a water-to-water heat pump to deliver radiant, in-floor heating at the ground level, maintaining a stable temperature.
Waste Heat Usage: The heat pumps can be used in tandem with nuclear reactor waste heat (approx. 210 kW of thermal energy per 40 kWe reactor) to warm the surrounding regolith barrier, which helps keep the dome insulated.
Thermal Conductivity Management: The system would need to ensure the ground remains frozen outside the dome to prevent the leakage of liquid water or air through the soil, using the ice as a natural sealant.
Advantages and Challenges
Advantage - Efficiency: Ground source systems provide high efficiency, potentially reducing energy demand by 25-50% compared to conventional, less efficient systems.
Challenge - Installation: Drilling deep boreholes in Martian soil requires robust, heavy-duty mining equipment that must be brought from Earth or constructed locally.
Alternative: Given the high energy demand, a combination of thermal insulation (like an inflated dome with an insulating layer) and in-floor heating is often considered more practical than relying solely on heat pumps.
Given the scale, the heat pump would likely function as part of a hybrid system, managing the base temperature while, for instance, nuclear or solar-powered radiators handle peak heating/cooling loads
#24 Re: Exploration to Settlement Creation » WIKI Project Designing for Mars » Yesterday 09:09:08
Exploration style mission:
Designing a Mars food system involves creating integrated, closed-loop systems that blend pre-packaged rations with on-site production (hydroponics, cellular agriculture, insect farming) for nutrition, sustainability, and psychological well-being, addressing challenges like Martian soil toxicity, radiation, and resource limitations with technologies like AI climate control, specialized LEDs, water recycling, and nuclear power, as seen in concepts like NASA's Mars to Table Challenge and Project MarsGarden.
Core Components of the Food System
Pre-packaged Meals: Initial supply of nutrient-dense, shelf-stable foods, with some processed for variety (e.g., grain milling for bread).
Hydroponics/Aeroponics: Growing crops (leafy greens, herbs, small fruits, potatoes) without soil in nutrient-rich water, using filtered Martian water and LED lighting.
Cellular Agriculture: Culturing meat (like chicken) and fungi for protein, reducing reliance on Earth-based livestock.
Insect Farming: Crickets or mealworms provide efficient protein, requiring minimal space and resources.
Waste Recycling: Algae and fungi break down human waste and CO2 to create compost and O2, closing the loop.
Design Considerations & Technologies
Environment: Greenhouses (like MarsGarden) offer radiation shielding (via ice/water layers) and psychological benefits, creating a familiar Earth-like space.
Energy: Nuclear reactors provide consistent power, crucial for lighting and life support.
Water: Martian water ice is melted, filtered, and used for irrigation.
Soil: Martian regolith is toxic (perchlorates) and needs washing, enriching, or bypass through hydroponics.
Automation & AI: AI manages climate (lighting, temperature) and monitors plant health for autonomous operation.
Resource Efficiency: Focus on systems with minimal mass (Equivalent System Mass) and waste, maximizing water and nutrient recycling.
Key Challenges
Sustainability: Achieving independence from Earth resupply for multi-year missions.
Nutrition & Palatability: Ensuring balanced diets and combating "menu fatigue" with diverse, tasty foods.
System Integration: Seamlessly blending different technologies (hydroponics, bioreactors) with life support systems.
Acceptability: Overcoming potential aversion to novel foods like algae or insect protein.
Current Efforts
NASA's Deep Space Food Challenge & "Mars to Table": Global competitions seeking integrated, self-sustaining food system designs.
CHAPEA (Crew Health and Performance Exploration Analog): Testing food systems in Mars-analog environments.
Project HOME (Hydroponic Operations for Mars Exploration): Researching hydroponic systems and crop yields (e.g., Moringa oleifera) under simulated Martian conditions
#25 Re: Exploration to Settlement Creation » WIKI Project Designing for Mars » Yesterday 09:08:54
project design to produce food for mars crew sizes during science missions
Designing a food system for Mars missions involves integrating prepackaged staples, hydroponics/aeroponics for fresh produce, and novel methods like bioreactors for protein, all managed by AI with 3D printing for customization, to ensure nutrition, prevent menu fatigue, minimize waste, and support crew morale through variety and flavor, addressing challenges like resource scarcity, toxicity, and microgravity effects. NASA's "Mars to Table" challenge pushes for holistic, self-sustaining designs combining these technologies, from waste recycling to nutrient synthesis, for long-duration independence.
Key Components of a Mars Food System
Prepackaged Food & Preparation:
Staples: Shelf-stable, nutrient-dense, space-optimized foods, with advanced packaging to protect against light, gases, and physical stress.
Processing: Equipment for mixing, heating (under reduced pressure), and sterilization, possibly using bioreactors for converting waste products.
Fresh Produce (Hydroponics/Aeroponics):
Gardens: Closed-loop systems using mineral-laced water (hydroponics) or mist (aeroponics) for vegetables (carrots, peppers) and fruits.
Light & Water: LED lighting and mirrors to supplement Mars' weaker sunlight; filtered Martian ice for irrigation.
Novel Production Methods:
Microbial/Gas Fermentation (HOBI-WAN): Using bacteria, electricity, air (CO2, H2), and recycled urea (from urine) to create protein-rich powders, reducing reliance on Earth supplies.
Cellular Agriculture: Potential for lab-grown meat for complete nutrition and variety.
Technology & Logistics:
3D Printing: Synthesizing food from macronutrient powders (proteins, starches, fats) with added flavors/micronutrients, offering customization and reducing waste.
AI & Automation: Managing climate control, nutrient delivery, and recipe generation for optimal health and morale.
Challenges & Solutions
Martian Soil: Toxic (perchlorates); needs washing, enriching, or bypassing with soilless systems.
Microgravity/Partial Gravity: Affects fluid dynamics, bubble behavior, and microbial settlement; requires forced mixing and tailored system design.
Waste Management: Recycling urine (nitrogen source) and organic waste into compost/nutrients.
Menu Fatigue: Variety is crucial for long-term physical and mental health, addressed by combining sources and adding flavor/texture options.
Project Design Example (Integrated System)
A Mars food system integrates these: a core bioreactor for protein, hydroponic bays for greens, 3D printers for varied textures, and pre-packaged essentials, all managed by an AI system that adjusts recipes based on crew needs and available resources, turning waste into nutrients for a truly self-sufficient cycle