Difference between revisions of "Team:Stanford-Brown/Vision"

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   <p class="pf">When launching satellites, probes, telescopes, and manned spacecraft into orbit, volume is everything. Because rockets need to fly through the atmosphere at supersonic speeds, payloads need to be packed into sleek, aerodynamic fairings at the tip of the rocket. A typical fairing has a diameter of just 5 meters. Carrying up large structures like solar panels and telescope mirrors requires the use of compact folding for launch.</p>
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   <p>When launching satellites, probes, telescopes, and manned spacecraft into orbit, volume is everything. Because rockets need to fly through the atmosphere at supersonic speeds, payloads need to be packed into sleek, aerodynamic fairings at the tip of the rocket. A typical fairing has a diameter of just 5 meters. Carrying up large structures like solar panels and telescope mirrors requires the use of compact folding for launch.</p>
  
 
<img class="featurette-image img-responsive center-block" src="https://static.igem.org/mediawiki/2015/8/8c/SB2015_ISSdiagram.jpg" alt="show the picture">  
 
<img class="featurette-image img-responsive center-block" src="https://static.igem.org/mediawiki/2015/8/8c/SB2015_ISSdiagram.jpg" alt="show the picture">  
  
   <p class="pf">Origami is already used heavily in the space industry. To name just one example, the Ultraflex Solar Array used on the Mars Phoenix Lander deploys by unfolding many isosceles triangles into a circle.</p>
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   <p>Origami is already used heavily in the space industry. To name just one example, the Ultraflex Solar Array used on the Mars Phoenix Lander deploys by unfolding many isosceles triangles into a circle.</p>
  
 
<img class="featurette-image img-responsive center-block" src="https://static.igem.org/mediawiki/2015/4/45/SB2015_Ultraflex.jpg" alt="show the picture">  
 
<img class="featurette-image img-responsive center-block" src="https://static.igem.org/mediawiki/2015/4/45/SB2015_Ultraflex.jpg" alt="show the picture">  
  
   <p class="pf">Our project goal is to develop the concept of origami in space further, by making the structures (1) self-folding and self-unfolding, and (2) produced biologically, which allows for in-situ resource utilization. We envision many possible uses for BiOrigami. Repositories of hundreds of different structures could be sent on manned missions flat-packed as reams of paper for on-demand use by astronauts. Self-folding structures could be used to deploy inflatable habitats, solar arrays, sun shields, and more. Small, self-unfolding paper-based probes could be dispersed around the Martian surface and relay weather information, relying on solar power.</p>
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   <p>Our project goal is to develop the concept of origami in space further, by making the structures (1) self-folding and self-unfolding, and (2) produced biologically, which allows for in-situ resource utilization. We envision many possible uses for BiOrigami. Repositories of hundreds of different structures could be sent on manned missions flat-packed as reams of paper for on-demand use by astronauts. Self-folding structures could be used to deploy inflatable habitats, solar arrays, sun shields, and more. Small, self-unfolding paper-based probes could be dispersed around the Martian surface and relay weather information, relying on solar power.</p>
  
   <p class="pf">Dr. Peter Schultz is a planetary scientist specializing in impact cratering and volcanic modifications to planetary surfaces. Before becoming a Professor of Geological Sciences at Brown University, Dr. Schultz was a research associate at NASA Ames.</p>
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   <p>Dr. Peter Schultz is a planetary scientist specializing in impact cratering and volcanic modifications to planetary surfaces. Before becoming a Professor of Geological Sciences at Brown University, Dr. Schultz was a research associate at NASA Ames.</p>
  
   <p class="pf">Dr. Jim Head is a planetary scientist who has worked on NASA projects including the Apollo program, the Lunar Reconaissance Orbiter, and the MESSENGER Mercury orbiter. Dr. Head is a Professor of Geological Sciences at Brown University.</p>
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   <p>Dr. Jim Head is a planetary scientist who has worked on NASA projects including the Apollo program, the Lunar Reconaissance Orbiter, and the MESSENGER Mercury orbiter. Dr. Head is a Professor of Geological Sciences at Brown University.</p>
  
   <p class="pf">Dr. Erica Jawin info goes here</p>
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   <p>Dr. Erica Jawin info goes here</p>
  
   <p class="pf">Dr. Lauren Jozwiak received her PhD from Brown University in Geological Science and Planetary Volcanology. She currently studies lunar crater deformations at NASA's Goddard Space Flight Center.</p>
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   <p>Dr. Lauren Jozwiak received her PhD from Brown University in Geological Science and Planetary Volcanology. She currently studies lunar crater deformations at NASA's Goddard Space Flight Center.</p>
  
 
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Revision as of 16:55, 15 September 2015

The Vision

Our Vision for BiOrigami

Applying bioengineering to space exploration

BiOrigami can improve mission capabilities by conserving volume

We asked planetary science experts how self-folding structures could aid space exploration. Here is what they said.

When launching satellites, probes, telescopes, and manned spacecraft into orbit, volume is everything. Because rockets need to fly through the atmosphere at supersonic speeds, payloads need to be packed into sleek, aerodynamic fairings at the tip of the rocket. A typical fairing has a diameter of just 5 meters. Carrying up large structures like solar panels and telescope mirrors requires the use of compact folding for launch.

show the picture

Origami is already used heavily in the space industry. To name just one example, the Ultraflex Solar Array used on the Mars Phoenix Lander deploys by unfolding many isosceles triangles into a circle.

show the picture

Our project goal is to develop the concept of origami in space further, by making the structures (1) self-folding and self-unfolding, and (2) produced biologically, which allows for in-situ resource utilization. We envision many possible uses for BiOrigami. Repositories of hundreds of different structures could be sent on manned missions flat-packed as reams of paper for on-demand use by astronauts. Self-folding structures could be used to deploy inflatable habitats, solar arrays, sun shields, and more. Small, self-unfolding paper-based probes could be dispersed around the Martian surface and relay weather information, relying on solar power.

Dr. Peter Schultz is a planetary scientist specializing in impact cratering and volcanic modifications to planetary surfaces. Before becoming a Professor of Geological Sciences at Brown University, Dr. Schultz was a research associate at NASA Ames.

Dr. Jim Head is a planetary scientist who has worked on NASA projects including the Apollo program, the Lunar Reconaissance Orbiter, and the MESSENGER Mercury orbiter. Dr. Head is a Professor of Geological Sciences at Brown University.

Dr. Erica Jawin info goes here

Dr. Lauren Jozwiak received her PhD from Brown University in Geological Science and Planetary Volcanology. She currently studies lunar crater deformations at NASA's Goddard Space Flight Center.

The full interview! See it in all its glory!

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