Difference between revisions of "Sintered Regolith"

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==Sintered Regolith==
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[[image:MLS1_Brick.GIF|thumb|A brick of MLS-1 basalt sintered at 1100 degrees Celsius for 2 hours.  Click to Enlarge]]
 
Sintered [[regolith]] falls into the category of ceramic materials as sintering is the process most common to ceramics.  When bricks are made from clay on Earth, first the bricks are heated long enough and hot enough to drive out the water.  Then the heating is increased to cause partial melting or vitrification which results in the edges of adjacent grains being bonded together once they have cooled.  The unmelted particles provide a stable shape and size during the process which involves some shrinkage and a decrease in porosity.
 
Sintered [[regolith]] falls into the category of ceramic materials as sintering is the process most common to ceramics.  When bricks are made from clay on Earth, first the bricks are heated long enough and hot enough to drive out the water.  Then the heating is increased to cause partial melting or vitrification which results in the edges of adjacent grains being bonded together once they have cooled.  The unmelted particles provide a stable shape and size during the process which involves some shrinkage and a decrease in porosity.
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===Lunar Considerations===  
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==Lunar Considerations==  
On Luna water for mixing the various particles would be very expensive and recycling the water would never be 100% effective.  It has been demonstrated that the sintering of dry regolith simulant will provide satisfactory bricks, and there is the example of mixing dry powders for [[powder metallurgy]], which is a sintering process performed on Earth and involves putting the material under pressure.  Compaction of lunar simulant using vibration has been [http://ares.jsc.nasa.gov/HumanExplore/Exploration/EXLibrary/DOCS/EIC049.HTML demonstrated] by NASA, but this method may not be as effective or may require more time in the reduced gravity of the moon.  More will be known about the quality of bricks possible from lunar materials when the research can be done on Luna.  A possibility to consider is the [[Sintered Brick Construction|sintering of bricks]] in an oxygen atmosphere as opposed to in a vacuum.
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On Luna water for mixing the various particles would be very expensive and recycling the water would never be 100% effective.  It has been demonstrated that the sintering of dry regolith simulant will provide satisfactory bricks, and there is the example of mixing dry powders for [[powder metallurgy]], which is a sintering process performed on Earth and involves putting the material under pressure.  Compaction of lunar simulant using vibration has been [http://ares.jsc.nasa.gov/HumanExplore/Exploration/EXLibrary/DOCS/EIC049.HTML demonstrated] by NASA, but this method may not be as effective or may require more time in the reduced gravity of the moon.  More will be known about the quality of bricks possible from lunar materials when the research can be done on Luna.  A possibility to consider is the [[Sintered Brick Construction|sintering of bricks]] in an oxygen atmosphere as opposed to in a vacuum. Fine particles in an insulating vacuum have the tendency to stick together due to friction which generates a static charge between adjacent, non-conducting particles.  Sintering regolith in an oxygen atmosphere has the potential to provide an atmospheric ground but may also result in a loss of oxygen due to oxidation.  However, oxygen is plentiful on Luna and experimentation will show if there is benefit to balance the cost.  Some low partial pressure of oxygen could conceivably be found best for the process of sintering bricks.  Another alternative is the use of a hydrogen atmosphere which results in a net gain of oxygen and will be discussed later.
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==Radiant Heating==
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Experiments in radiant heating of regolith simulant have been carried out by NASA Johnson Space Center and Lockheed Engineering & Sciences Co.  [http://www.nss.org/settlement/spaceresources/1998-InSituResourcesForConstructionOfPlanetaryOutposts.pdf Results] show that radiant heating can reproducibly sinter large, strong bricks in a fused silica mold.  Fused silica was chosen for its combination of extremely low thermal conductivity and low density.
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Uniform bricks measuring 7.9 x 5.5 x 3.6 cm were produced by heating [[MLS-1]] [[Basalt]] for two hours at 1,100 degrees Celsius.  Resulting bricks were crack free except for small expansion cracks near the top surface, with negligible reductions in volume and density.
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Larger bricks were produced from the glass-rich simulant [[JSC-1]].  The sample was initially compacted using vibration for 5 minutes until reaching 2.45 grams/cm<sup>3</sup>, and then sintered for 2.5 hours at 1,100 degrees Celsius.  A silica fabric liner was inserted between the simulant and the fused silica mold to prevent the brick from sintering to the mold.
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==Microwave Heating==
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In experiments, pure microwave heating has been unsuccessful in producing usable bricks.  Due to the thermal insulating properties of crushed lunar regolith and it's simulants, the insides of the bricks melt while the outside remains unsintered.  While not useful for this purpose, microwave heating may be found useful for foundation preparation, permanent grading, road construction, dust remediation, and applications for which molten regolith is required.
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[[image:MLS1_Brick_cross_section.GIF|left|thumb|An electron micrograph of a cross section of sintered MLS-1 basalt brick, showing bonding at grain to grain contacts.  Click Image to Enlarge.]]
  
 
==Hybrid Microwave Sintering==
 
==Hybrid Microwave Sintering==
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The crucible was surrounded by silicon carbide bricks, which converted part of the 2.45GHz microwave energy to heat. This radiant heating kept the outside of the regolith hot while microwaves heated the inside at the same temperature of 980 degrees Celsius for 35 minutes.  Microwave power was then slowly reduced over several hours.  The result was an evenly heated and cooled sintered block with no fractures capable of withstanding up to approximately 1,100 psi.
 
The crucible was surrounded by silicon carbide bricks, which converted part of the 2.45GHz microwave energy to heat. This radiant heating kept the outside of the regolith hot while microwaves heated the inside at the same temperature of 980 degrees Celsius for 35 minutes.  Microwave power was then slowly reduced over several hours.  The result was an evenly heated and cooled sintered block with no fractures capable of withstanding up to approximately 1,100 psi.
 
===Oxygen Retrieval and Magnetic Handling===
 
===Oxygen Retrieval and Magnetic Handling===
Hybrid microwave sintering in a flowing hydrogen atmosphere resulted in the reduction of [[iron oxide]] to produce [[iron]] in the sample and [[water]] which escaped as vapor.  This additional process provides a means of oxygen retrieval as well as increasing the iron content so that bricks can be lifted using a magnet.
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Hybrid microwave sintering in a flowing [[hydrogen]] atmosphere resulted in the reduction of [[iron oxide]] to produce [[iron]] in the sample and [[water]] which escaped as vapor.  This additional process provides a means of [[oxygen|oxygen retrieval]] as well as increasing the iron content so that bricks can be lifted using a magnet.
  
 
==External Links==
 
==External Links==
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*[http://coewww.rutgers.edu/~benaroya/publications/Ruess%20et%20al%20ASCE%20JAE.pdf Structural Design of a Lunar Habitat - Journal of Aerospace Engineering, July 2006, pg 137] .. PDF
 
*[http://coewww.rutgers.edu/~benaroya/publications/Ruess%20et%20al%20ASCE%20JAE.pdf Structural Design of a Lunar Habitat - Journal of Aerospace Engineering, July 2006, pg 137] .. PDF
 
*[http://www.nss.org/settlement/spaceresources/1998-InSituResourcesForConstructionOfPlanetaryOutposts.pdf Workshop on using In-Situ resources for construction of planetary outposts - LPI] .. PDF
 
*[http://www.nss.org/settlement/spaceresources/1998-InSituResourcesForConstructionOfPlanetaryOutposts.pdf Workshop on using In-Situ resources for construction of planetary outposts - LPI] .. PDF
*[http://ares.jsc.nasa.gov/HumanExplore/Exploration/EXLibrary/DOCS/EIC049.HTML Sintering Bricks on the Moon - NASA JSC]
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*[http://ares.jsc.nasa.gov/HumanExplore/Exploration/EXLibrary/DOCS/EIC049.HTML Sintering Bricks on the Moon - NASA JSC]{{dead link}}
*[http://gsfctechnology.gsfc.nasa.gov/Cardiff.pdf Vacuum Pyrolysis and Related ISRU Techniques - NASA GSFC] .. PDF
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*[http://gsfctechnology.gsfc.nasa.gov/Cardiff.pdf Vacuum Pyrolysis and Related ISRU Techniques - NASA GSFC] .. PDF{{dead link}}

Latest revision as of 14:46, 10 April 2019

This article is incomplete or needs more information. You can help Lunarpedia by expanding or correcting it.


A brick of MLS-1 basalt sintered at 1100 degrees Celsius for 2 hours. Click to Enlarge

Sintered regolith falls into the category of ceramic materials as sintering is the process most common to ceramics. When bricks are made from clay on Earth, first the bricks are heated long enough and hot enough to drive out the water. Then the heating is increased to cause partial melting or vitrification which results in the edges of adjacent grains being bonded together once they have cooled. The unmelted particles provide a stable shape and size during the process which involves some shrinkage and a decrease in porosity.

Lunar Considerations

On Luna water for mixing the various particles would be very expensive and recycling the water would never be 100% effective. It has been demonstrated that the sintering of dry regolith simulant will provide satisfactory bricks, and there is the example of mixing dry powders for powder metallurgy, which is a sintering process performed on Earth and involves putting the material under pressure. Compaction of lunar simulant using vibration has been demonstrated by NASA, but this method may not be as effective or may require more time in the reduced gravity of the moon. More will be known about the quality of bricks possible from lunar materials when the research can be done on Luna. A possibility to consider is the sintering of bricks in an oxygen atmosphere as opposed to in a vacuum. Fine particles in an insulating vacuum have the tendency to stick together due to friction which generates a static charge between adjacent, non-conducting particles. Sintering regolith in an oxygen atmosphere has the potential to provide an atmospheric ground but may also result in a loss of oxygen due to oxidation. However, oxygen is plentiful on Luna and experimentation will show if there is benefit to balance the cost. Some low partial pressure of oxygen could conceivably be found best for the process of sintering bricks. Another alternative is the use of a hydrogen atmosphere which results in a net gain of oxygen and will be discussed later.

Radiant Heating

Experiments in radiant heating of regolith simulant have been carried out by NASA Johnson Space Center and Lockheed Engineering & Sciences Co. Results show that radiant heating can reproducibly sinter large, strong bricks in a fused silica mold. Fused silica was chosen for its combination of extremely low thermal conductivity and low density.

Uniform bricks measuring 7.9 x 5.5 x 3.6 cm were produced by heating MLS-1 Basalt for two hours at 1,100 degrees Celsius. Resulting bricks were crack free except for small expansion cracks near the top surface, with negligible reductions in volume and density.

Larger bricks were produced from the glass-rich simulant JSC-1. The sample was initially compacted using vibration for 5 minutes until reaching 2.45 grams/cm3, and then sintered for 2.5 hours at 1,100 degrees Celsius. A silica fabric liner was inserted between the simulant and the fused silica mold to prevent the brick from sintering to the mold.

Microwave Heating

In experiments, pure microwave heating has been unsuccessful in producing usable bricks. Due to the thermal insulating properties of crushed lunar regolith and it's simulants, the insides of the bricks melt while the outside remains unsintered. While not useful for this purpose, microwave heating may be found useful for foundation preparation, permanent grading, road construction, dust remediation, and applications for which molten regolith is required.

An electron micrograph of a cross section of sintered MLS-1 basalt brick, showing bonding at grain to grain contacts. Click Image to Enlarge.

Hybrid Microwave Sintering

Research conducted by NASA Johnson Space Center and Lockheed Engineering & Sciences Co. has indicated that the lunar simulant MLS-1 can be successfully sintered using a combination of both microwave and radiant heating.

The crucible was surrounded by silicon carbide bricks, which converted part of the 2.45GHz microwave energy to heat. This radiant heating kept the outside of the regolith hot while microwaves heated the inside at the same temperature of 980 degrees Celsius for 35 minutes. Microwave power was then slowly reduced over several hours. The result was an evenly heated and cooled sintered block with no fractures capable of withstanding up to approximately 1,100 psi.

Oxygen Retrieval and Magnetic Handling

Hybrid microwave sintering in a flowing hydrogen atmosphere resulted in the reduction of iron oxide to produce iron in the sample and water which escaped as vapor. This additional process provides a means of oxygen retrieval as well as increasing the iron content so that bricks can be lifted using a magnet.

External Links