Difference between revisions of "Shared:2023W4G2Design"

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<span style="font-size: 40.5px; color: grey;">'''Settling in the cracks of Mars'''</span><br>
  
[[File:AR0122-IAPW-2023_Group2_Week2_ConceptPresentation_1.png|850px]]
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'''Group 2''':  Mohammad Behboodi - Sumeet Joshi - Dost Sahingoz - Majd Shahoud
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'''Group 2''':  Mohammad Behboodi - Sumeet Joshi - Dost Sahingoz - Majd Shahoud                
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=='''DESIGN APPROACH'''==
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=='''INTRO'''==
  
  
we began the design by studying the existing references. Based on reference research, Underground rhizomatic structure with skylights, [http://cs.roboticbuilding.eu/index.php/2019MSc3 Rhizome 1.0] and some other researches, building underground has many advantages, such as better temperature control against drastic shifts and protection from harmful radiation on Mars. "Dust storms, cosmic rays and solar winds ravage the Red Planet's surface. But belowground, some life might find refuge. "The environment with the best chance of habitability on Mars is the subsurface," says Jesse Tarnas, a planetary scientist at NASA's Jet Propulsion Laboratory and the new study’s lead author. Examining the Martian underground could help scientists learn whether life could have survived there — and the best subsurface samples available today are Martian meteorites that have crash-landed on Earth." [https://www.space.com/martian-crust-could-sustain-life-through-radiation Martian crust could sustain life through radiation]
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We began the design by studying the existing reference projects. According to prior research, an underground rhizomatic structure with skylights, [http://cs.roboticbuilding.eu/index.php/2019MSc3 Rhizome 1.0], it seems evident that building underground has many advantages. For example, a better temperature control against drastic shifts and protection from harmful radiation on Mars. "Dust storms, cosmic rays and solar winds ravage the Red Planet's surface. But belowground, some life might find refuge". [https://www.space.com/martian-crust-could-sustain-life-through-radiation Martian crust could sustain life through radiation]. The excavation of martian soil is a labor intensive task that could cost valueble time. Rather than digging in the soil, the existing cracks in the martian surface can be used as underground spaces for the habitat.
  
Choosing the location on Mars:
 
  
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==Choosing the LOCATION on Mars==:
  
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The fractured surface polygons that can be seen around the craters on mars. Scientists estimate that on the surface of Mars, there are more than 43,000 impact craters with diameters greater than 5 kilometers. "The Martian crater polygons shows cracks on both large and small size scales. The larger cracks are more than 100 metres long and up to 10 metres wide". this pattern resembles the pattern of dried-up mud pools on earth. Places on Mars that show polygonal ground may indicate where future colonists may find water ice. [https://www.newscientist.com/gallery/mars-cracks-driedlakes/ Cracks on Mars]
  
Polygonal, shaped soil is quite common in some areas of Mars. It is widely believed that this is caused by the sublimation of ice from the ground. Sublimation is the direct change of solid ice into a gas. This is similar to what happens to dry ice on Earth. Places on Mars that show polygonal ground may indicate where future colonists may find water ice. Low center polygons have been suggested as markers for ground ice.
 
  
[[File: crater on Mars.jpg|400px]]  [[File:Polygonal_Patterned_Ground.jpg|300px]]  
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[[File: crater on Mars.jpg|400px]]  [[File:Polygonal_Patterned_Ground.jpg|350px]]  
  
 
(Image credit: NASA/JPL/University of Arizona)
 
(Image credit: NASA/JPL/University of Arizona)
  
  
[[File:AR0122-IAPW-2023_Group2_Week2_ConceptPresentation_2.png|850px]]
 
  
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'''Design Principles'''
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[[File:Design_Process_for_Wiki.jpg|750px]]
  
[[File:AR0122-IAPW-2023_Group2_Week2_ConceptPresentation_3.png|850px]]
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'''1:20 Model'''
  
 
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[[File:IAP2023_group2_3Dprinted_model.jpg|700px]]
[[File:AR0122-IAPW-2023_Group2_Week2_ConceptPresentation_4.png|850px]]
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[[File:AR0122-IAPW-2023_Group2_Week2_ConceptPresentation_5.png|850px]]
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=='''Material'''==
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Using regolith-based concrete that can be produced via In-Situ Resource Utilisation (ISRU).
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=='''Prototyping and Production methode'''==
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Latest revision as of 06:44, 25 April 2023


Settling in the cracks of Mars


Render view 1 cut.jpg


Group 2: Mohammad Behboodi - Sumeet Joshi - Dost Sahingoz - Majd Shahoud




INTRO

We began the design by studying the existing reference projects. According to prior research, an underground rhizomatic structure with skylights, Rhizome 1.0, it seems evident that building underground has many advantages. For example, a better temperature control against drastic shifts and protection from harmful radiation on Mars. "Dust storms, cosmic rays and solar winds ravage the Red Planet's surface. But belowground, some life might find refuge". Martian crust could sustain life through radiation. The excavation of martian soil is a labor intensive task that could cost valueble time. Rather than digging in the soil, the existing cracks in the martian surface can be used as underground spaces for the habitat.


==Choosing the LOCATION on Mars==:

The fractured surface polygons that can be seen around the craters on mars. Scientists estimate that on the surface of Mars, there are more than 43,000 impact craters with diameters greater than 5 kilometers. "The Martian crater polygons shows cracks on both large and small size scales. The larger cracks are more than 100 metres long and up to 10 metres wide". this pattern resembles the pattern of dried-up mud pools on earth. Places on Mars that show polygonal ground may indicate where future colonists may find water ice. Cracks on Mars


Crater on Mars.jpg Polygonal Patterned Ground.jpg

(Image credit: NASA/JPL/University of Arizona)


Design Principles Design Process for Wiki.jpg

1:20 Model

IAP2023 group2 3Dprinted model.jpg